[Federal Register: February 29, 2008 (Volume 73, Number 41)]
[Rules and Regulations]
[Page 11283-11304]
From the Federal Register Online via GPO Access [wais.access.gpo.gov]
[DOCID:fr29fe08-26]
[[Page 11283]]
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Part IV
Department of Labor
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Mine Safety and Health Administration
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30 CFR Parts 56, 57, and 71
Asbestos Exposure Limit; Final Rule
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DEPARTMENT OF LABOR
Mine Safety and Health Administration
30 CFR Parts 56, 57, and 71
RIN 1219-AB24
Asbestos Exposure Limit
AGENCY: Mine Safety and Health Administration, Labor.
ACTION: Final rule.
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SUMMARY: The Mine Safety and Health Administration (MSHA) is revising
its existing health standards for asbestos exposure at metal and
nonmetal mines, surface coal mines, and surface areas of underground
coal mines. This final rule reduces the permissible exposure limits for
airborne asbestos fibers and makes clarifying changes to the existing
standards. Exposure to asbestos has been associated with lung cancer,
mesothelioma, and other cancers, as well as asbestosis and other
nonmalignant respiratory diseases. This final rule will help improve
health protection for miners who work in an environment where asbestos
is present and lower the risk that miners will suffer material
impairment of health or functional capacity over their working
lifetime.
DATES: This final rule is effective April 29, 2008.
FOR FURTHER INFORMATION CONTACT: Patricia W. Silvey at
silvey.patricia@dol.gov (E-mail), 202-693-9440 (Voice), or 202-693-9441
(Fax).
SUPPLEMENTARY INFORMATION: The outline of this preamble is as follows:
I. Summary
II. Background to the Final Rule
A. Scope of Final Rule
B. Mineralogy and Analytical Methods for Asbestos
C. Summary of Asbestos Health Hazards
D. Factors Affecting the Occurrence and Severity of Disease
E. MSHA Asbestos Standards
F. OSHA Asbestos Standards
III. Asbestos Exposures in Mines
A. Where Asbestos Is Found at Mines
B. Sampling Data and Exposure Calculations
C. Summary of MSHA's Asbestos Air Sampling and Analysis Results
D. Prevention of Asbestos Take-Home Contamination
IV. Application of OSHA'S Risk Assessment to Mining
A. Summary of OSHA's Risk Assessment
B. Risk Assessment for the Mining Industry
C. Characterization of the Risk to Miners
V. Section-by-Section Analysis of Final Rule
A. Sections 56/57.5001(b)(1) and 71.702(a): Definitions
B. Sections 56/57.5001(b)(2) and 71.702(b): Permissible Exposure
Limits (PELs)
C. Sections 56/57.5001(b)(3) and 71.702(c): Measurement of
Airborne Fiber Concentration
D. Section 71.701(c) and (d): Sampling; General Requirements
VI. Regulatory Analyses
A. Executive Order (E.O.) 12866
B. Feasibility
C. Alternatives Considered
D. Regulatory Flexibility Analysis (RFA) and Small Business
Regulatory Enforcement Fairness Act (SBREFA)
E. Other Regulatory Considerations
VII. Copy of the OSHA Reference Method (ORM)
VIII. References Cited in the Preamble
I. Summary
The final rule lowers MSHA's permissible exposure limits (PELs) for
asbestos; incorporates the Occupational Safety and Health
Administration (OSHA) Reference Method (29 CFR 1910.1001, Appendix A)
for MSHA's analysis of mine air samples for asbestos; and makes several
clarifying changes to MSHA's existing rule. MSHA is issuing this health
standard limiting miners' exposure to asbestos under section
101(a)(6)(A) of the Federal Mine Safety and Health Act of 1977 (Mine
Act). MSHA based this final rule on its experience, an assessment of
the health risks of asbestos, OSHA's rulemaking history and enforcement
experience with its asbestos standard and public comments and testimony
on MSHA's asbestos proposed rule.
To protect the health of miners, this final rule lowers MSHA's 8-
hour, time-weighted average (TWA), full-shift PEL from 2 fibers per
cubic centimeter of air (f/cc) to 0.1 f/cc. The existing excursion
limit for metal and nonmetal mines is 10 fibers per milliliter (f/mL)
for 15 minutes and the existing excursion limit for coal mines is 10 f/
cc for a total of 1 hour in each 8-hour day. This final rule lowers
these existing excursion limits to 1 f/cc for 30 minutes. Together,
these lower PELs significantly reduce the risk of material impairment
for exposed miners. These final PELs are the same as proposed and the
same as OSHA's asbestos exposure limits. Although OSHA stated in the
preamble to its 1994 final rule (59 FR 40967) that there is a remaining
significant risk of material impairment of health or functional
capacity at the 0.1 f/cc limit, OSHA concluded that this concentration
is ``the practical lower limit of feasibility for measuring asbestos
levels reliably.'' MSHA agrees with this conclusion.
To clarify the criteria for the analytical method that MSHA will
use to analyze mine air samples for asbestos under this final rule, the
rule includes a reference to Appendix A of OSHA's asbestos standard (29
CFR 1910.1001). Appendix A specifies basic elements of a phase contrast
microscopy (PCM) method for analyzing airborne asbestos samples, which
includes the same basic analytical elements as those specified in
MSHA's existing standards.
Because the risk assessment used as the basis for MSHA's asbestos
PELs relies on PCM-based methodology, MSHA will continue to use PCM as
the primary methodology for analyzing air samples to determine
compliance with the PELs. PCM provides a relatively quick and cost-
effective analysis of asbestos samples. In addition, MSHA will continue
to follow-up with its policy of using a transmission electron
microscopy (TEM) analysis when PCM results indicate a potential
overexposure.
MSHA, however, encourages the development of analytical methods
specifically for asbestos in mine air samples. MSHA will consider using
a method statistically equivalent to Appendix A, if it meets the OSHA
Reference Method (ORM) equivalency criteria in OSHA's asbestos standard
[29 CFR 1910.1001(d)(6)(iii)] and is recognized by a laboratory
accreditation organization. For example, ASTM D7200-06, ``Standard
Practice for Sampling and Counting Airborne Fibers, Including Asbestos
Fibers, in Mines and Quarries, by Phase Contrast Microscopy and
Transmission Electron Microscopy,'' contains the same procedure as
NIOSH 7400 to identify fibers. ASTM D7200-06 then has an additional
procedure to discriminate potential asbestos fibers, which NIOSH 7400
does not. NIOSH is supporting an ASTM inter-laboratory study to
determine whether this additional procedure can be performed accurately
and consistently. This procedure was developed in part as a result of
this rulemaking and has not been validated.
II. Background to the Final Rule
A. Scope of Final Rule
This final rule applies to all metal and nonmetal mines, surface
coal mines, and surface areas of underground coal mines. It is
substantively unchanged from the proposed rule and contains the same
PELs and analytical method as in OSHA's asbestos standard. Some
commenters supported additional changes to MSHA's definition of
asbestos and its analytical method. Others recommended that MSHA
propose additional requirements from the OSHA asbestos standard to
prevent take-home contamination. Such changes were not contemplated in
the proposed
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rule and, therefore, are beyond the scope of this final rule.
B. Mineralogy and Analytical Methods for Asbestos
Asbestos is a generic term used to describe the fibrous habits of
specific naturally occurring, hydrated silicate minerals. Several
federal agencies \1\ have regulations that address six asbestos
minerals: chrysotile, crocidolite, cummingtonite-grunerite asbestos
(amosite), actinolite asbestos, anthophyllite asbestos, and tremolite
asbestos. Other agencies address asbestos more generally.\2\
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\1\ In addition to MSHA's and OSHA's existing worker protection
standards, other federal statutory and regulatory requirements that
apply only to the six commercial varieties of asbestos include the
Asbestos Hazard Emergency Response Act (AHERA) [15 U.S.C. 2642(3)]
and the Clean Air Act's National Emission Standards for Hazardous
Air Pollutants (NESHAP) [40 CFR 61.141].
\2\ Asbestos is listed as a hazardous air pollutant under the
Clean Air Act [42 U.S.C. 7412(b)(1)]; as a hazardous substance under
the Comprehensive Environmental Response, Compensation and Liability
Act [40 CFR 302.4]; and in EPA's Integrated Risk Information System
(IRIS), a collection of health assessment information regarding the
toxicity of asbestos, http://www.epa.gov/IRIS/susbst/0371.htm.
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The terminology used to refer to how minerals form and how they are
named is complex. Much of the existing health risk data for asbestos
uses the commercial mineral terminology.\3\ In the asbestiform habit,
mineral crystals grow forming long, thread-like fibers. The U.S. Bureau
of Mines defined asbestiform minerals to be ``a certain type of mineral
fibrosity in which the fibers and fibrils possess high tensile strength
and flexibility.'' \4\ When light pressure is applied to an asbestiform
fiber, it bends much like a wire, rather than breaks. In the
nonasbestiform habit, mineral crystals do not grow in long thin fibers;
they grow in a more massive habit. When pressure is applied, the
nonasbestiform crystals fracture into prismatic particles, which are
called cleavage fragments because they result from the particle's
breaking or cleavage. Cleavage fragments may be formed when nonfibrous
minerals are crushed, as may occur in mining and milling operations.
Distinguishing between asbestiform fibers and cleavage fragments in
certain size ranges can be difficult or impossible for some
minerals.\5\
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\3\ Asbestos mineralogy was discussed more fully in the proposed
rule (70 FR 43952-43953).
\4\ U.S. Bureau of Mines (Campbell et al.), 1977.
\5\ Meeker et al., 2003.
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C. Summary of Asbestos Health Hazards
Studies first identified health problems associated with
occupational exposure to asbestos in the early 20th century among
workers involved in the manufacturing or use of asbestos-containing
products.\6\ These studies identified the inhalation of asbestos as the
cause of asbestosis, a slowly progressive disease that produces lung
scarring and loss of lung elasticity. Studies also found that asbestos
caused lung and several other types of cancer.\7\ For example,
mesotheliomas, rare cancers of the lining of the chest or abdominal
cavities, are almost exclusively attributable to asbestos exposure.
Once diagnosed, they are rapidly fatal. The damage following many years
of workplace exposure to asbestos is generally cumulative and
irreversible. Most asbestos-related diseases have long latency periods,
typically not producing symptoms for 20 to 30 years following initial
exposure. Studies also indicate adverse health effects in workers who
have had relatively brief exposures to asbestos.\8\
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\6\ GETF Report, p. 38, 2003; OSHA (40 FR 47654), 1975.
\7\ Doll, 1955; Reeves et al., 1974; Becker et al., 2001; Browne
and Gee, 2000; Sali and Boffetta, 2000; IARC, 1987.
\8\ Sullivan, 2007.
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Several studies have examined respiratory health and respiratory
symptoms of asbestos-exposed workers.\9\ Asbestos-induced pleurisy is
the most common asbestos-related condition to occur during the 20-year
period immediately following a worker's first exposure to asbestos.\10\
Pleural plaques may develop within 10-20 years after an initial
asbestos exposure \11\ and slowly progress in size and amount of
calcification, independent of any further exposure. Diffuse pleural
thickening and pleural plaques are biologic markers reflecting previous
asbestos exposure.\12\ In addition, presence in lung tissue of asbestos
fibers with a coating of iron and protein, called asbestos bodies, is
one of the criteria that serve to support a pathologic diagnosis of
asbestosis.\13\ These nonmalignant respiratory conditions can be used
to identify at-risk miners prior to their developing a more serious
asbestos disease.
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\9\ Wang et al., 2001; Delpierre et al., 2002; Eagen et al.,
2002; Selden et al., 2001.
\10\ Rudd, 2002.
\11\ Bolton et al., 2002; OSHA, 1986.
\12\ ATSDR, 2001; Manning et al., 2002.
\13\ ATSDR, 2001; Peacock et al., 2000; Craighead et al, 1982.
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Because the hazardous effects from exposure to asbestos are well
known, MSHA's discussion in this section will focus on the results of
studies and literature reviews published since the publication of
OSHA's risk assessment, and those involving miners. One such review by
Tweedale (2002) stated,
Asbestos has become the leading cause of occupational related
cancer death, and the second most fatal manufactured carcinogen
(after tobacco). In the public's mind, asbestos has been a hazard
since the 1960s and 1970s. However, the knowledge that the material
was a mortal health hazard dates back at least a century, and its
carcinogenic properties have been appreciated for more than 50
years.
Greenberg (2003) also published a recent review of the biological
effects of asbestos and provided a historical perspective similar to
that of Tweedale.
The three most commonly described adverse health effects associated
with asbestos exposure are lung cancer, mesotheliomas, and pulmonary
fibrosis (i.e., asbestosis). OSHA, in its 1986 asbestos rule, reviewed
each of these diseases and provided details on the studies
demonstrating the relationship between asbestos exposure and the
clinical evidence of disease.\14\ In 2001, the Agency for Toxic
Substances and Disease Registry (ATSDR) published an updated
Toxicological Profile for Asbestos that also included an extensive
discussion of these three diseases. A search of peer-reviewed
scientific literature yielded many new articles \15\ that continue to
demonstrate and support findings of asbestos-induced lung cancer,
mesotheliomas, and asbestosis, consistent with the conclusions of OSHA
and ATSDR. Thus, in the scientific community, there is compelling
evidence of the adverse health effects of asbestos exposure.
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\14\ Berry and Newhouse, 1983; Dement et al., 1982; Finkelstein,
1983; Henderson and Enterline, 1979; Peto, 1980; Peto et al., 1982;
Seidman et al., 1979; Seidman, 1984; Selikoff et al., 1979; Weill et
al., 1979.
\15\ Baron, 2001; Bolton et al., 2002; Manning et al., 2002;
Nicholson, 2001; Osinubi et al., 2000; Roach et al., 2002.
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D. Factors Affecting the Occurrence and Severity of Disease
The toxicity of asbestos, and the subsequent occurrence of disease,
is related to its concentration in the air and the duration of
exposure. Other variables, such as the fiber's characteristics or the
effectiveness of a person's lung clearance mechanisms, lung fiber
burden, residence-time-weighted cumulative exposures, and susceptible
populations are also relevant factors affecting disease severity.\16\
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\16\ ICRP, 1966; EPA, 1986; West, 2000 and 2003; Manning et al.,
2002.
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1. Fiber Concentration
Early airborne asbestos dust measurements had counted particles
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and reported the results as millions of particles per cubic foot of air
(mppcf). Most recent studies express the concentration of asbestos as
the number of fibers per cubic centimeter (f/cc). Some studies have
also reported asbestos concentrations in the number of fibers per
milliliter (f/mL), which is an equivalent concentration to f/cc. MSHA's
existing PELs for asbestos are expressed in f/mL for metal and nonmetal
mines and as f/cc for coal mines. To improve consistency and avoid
confusion, MSHA expresses the concentration of asbestos fibers as f/cc
in this final rule, for both coal and metal and nonmetal mines.
In the late 1960s, scientists correlated PCM-based fiber counting
methods with the earlier types of dust measurements, which provided a
means to estimate earlier workers' asbestos exposures and enabled
researchers to develop a dose-response relationship with the occurrence
of disease. The British Occupational Hygiene Society reported \17\ that
a worker exposed to 100 fiber-years per cubic centimeter (e.g., 50
years at 2 f/cc, 25 years at 4 f/cc, 10 years at 10 f/cc) would have a
1 percent risk of developing early signs of asbestosis. The correlation
of exposure levels with the disease experience of populations of
exposed workers provided a basis for setting an occupational exposure
limit for asbestos measured by the concentration of the fibers in air.
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\17\ Lane et al., 1968; OSHA (40 FR 47654), 1975; NIOSH, 1980.
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OSHA (51 FR 22617) applied a conversion factor of 1.4 to convert
mppcf, which includes all particles of respirable size, to f/cc, which
includes only those particles greater than 5 [mu]m in length with at
least a 3:1 aspect ratio. More recently, Hodgson and Darnton (2000)
recommended the use of a factor of 3. In reviewing the scientific
literature, MSHA did not critically evaluate the impact of these and
other conversion factors. MSHA notes this difference here for
completeness. MSHA is relying on OSHA's risk assessment and, thus, is
using OSHA's conversion factor.
2. Duration of Exposure
The duration of exposure (T) is reported in both epidemiological
and toxicological studies, and is generally much shorter in animal
studies (e.g., months versus years). In epidemiological studies
involving toxic substances that do not have acute health effects, such
as asbestos, duration of exposure is typically expressed in years.
3. Cumulative Exposure
When developing dose-response relationships for asbestos-induced
health effects, researchers typically use the product of exposure
concentration (C in f/cc) and exposure duration (T in years), expressed
as fiber-years,\18\ to indicate the level of exposure or dose. When
summed over all periods of exposure, this measure is called cumulative
exposure. Because of the difficulties in obtaining good quantitative
exposure assessments, cumulative exposure expressed in fiber-years is
often selected as the common metric for the levels of exposures
reported in epidemiological studies.
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\18\ ATSDR, 2001; Fischer et al., 2002; Liddell, 2001; Pohlabeln
et al., 2002.
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Finkelstein\19\ noted that this product of exposure concentration
times duration of exposure (C x T) assumes an equal weighting of each
variable (C, T). Finkelstein stated further that exposure at a low
concentration for a long period of time may be numerically equivalent
to exposure at a high concentration for short periods of time; but,
they may not be biologically equivalent. What this means is that, in
some studies, either concentration or duration of exposure may be more
important in predicting disease. For example, in the case of
mesothelioma risk following asbestos exposure, Finkelstein \20\
concluded that ``* * * duration of exposure may dominate the exposure
term * * *''.
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\19\ Finkelstein, 1995; ATSDR, p. 42, 2001.
\20\ Finkelstein, 1995
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4. Fiber Characteristics
Baron (2001) reviewed techniques for the measurement of fibers and
stated, ``* * * fiber dose, fiber dimension, and fiber durability are
the three primary factors in determining fiber toxicity * * *''.
Manning et al. (2002) also noted the important roles of bio-persistence
(i.e., durability), physical properties, and chemical properties in
defining the ``toxicity, pathogenicity, and carcinogenicity'' of
asbestos. Roach et al. (2002) stated that--
Physical properties, such as length, diameter, length-to-width
(aspect ratio), and texture, and chemical properties are believed to
be determinants of fiber distribution [in the body] and disease
severity.
Many other investigators \21\ also have concluded that the dimensions
of asbestos fibers are biologically important.
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\21\ ATSDR, 2001; ATSDR, 2003; Osinubi et al., 2000; Peacock et
al., 2000; Langer et al., 1979.
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The NIOSH 7400 analytical method used by MSHA's contract
laboratories specifies that analysts count those fibers that are
greater than 5 micrometers (microns, [mu]m) in length with a length to
diameter aspect ratio of at least 3:1. Several recent publications \22\
support this aspect ratio, although larger aspect ratios such as 5:1 or
20:1 have been proposed.\23\ There is some evidence that longer,
thinner asbestos fibers (e.g., greater than 20 [mu]m long and less than
1 [mu]m in diameter) are more potent carcinogens than shorter fibers.
Suzuki and Yuen (2002), however, concluded that ``Short, thin asbestos
fibers should be included in the list of fiber types contributing to
the induction of human malignant mesotheliomas * * * ''. More recently,
Dodson et al. (2003) concluded that all lengths of asbestos fibers
induce pathological responses and that researchers should exercise
caution when excluding a population of inhaled asbestos fibers based on
their length.
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\22\ ATSDR, 2001; Osinubi et al., 2000.
\23\ Wylie et al., 1985.
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Researchers have found neither a reliable method for predicting the
contribution of fiber length to the development of disease, nor
evidence establishing the exact relationship between them. There is
suggestive evidence that the dimensions of asbestos fibers may vary
with different diseases. A continuum may exist in which shorter, wider
fibers produce one disease, such as asbestosis, and longer, thinner
fibers produce another, such as mesotheliomas.\24\
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\24\ ATSDR, pp. 39-41, 2001; ATSDR, 2003; Mossman, pp. 47-50,
2003; Kuempel et al., 2006.
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Some commenters suggested that MSHA consider additional fiber
characteristics, such as durability, in evaluating risk. Some
emphasized that not all fibers with the same dimensions will lead to
the same disease endpoint. The science is inconclusive on the
relationship between the various fiber characteristics and the disease
endpoints.\25\
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\25\ Hodgson and Darnton, 2000; Browne, 2001; Liddell, 2001;
ATSDR, 2001.
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E. MSHA Asbestos Standards
The early PELs for asbestos in mining dropped dramatically as more
information on the health effects of asbestos exposure became evident
20 to 30 years (latency period) following its widespread use during the
1940s.
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Year 8-hour TWA, Asbestos PEL
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1967.............................. 5 mppcf (30 f/mL)
1969.............................. 2 mppcf (12 f/mL)
1974.............................. 5 f/mL for metal and nonmetal mines
1976.............................. 2 f/cc for surface areas of coal
mines (41 FR 10223)
1978.............................. 2 f/mL for metal and nonmetal mines
(43 FR 54064)
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On March 29, 2002 (67 FR 15134), MSHA published an advance notice
of proposed rulemaking to obtain public comment on how best to protect
miners from exposure to asbestos. MSHA published the proposed rule on
July 29, 2005 (70 FR 43950) and held two public hearings in October
2005.
F. OSHA's Asbestos Standards
Like MSHA's, OSHA's 8-hour TWA PEL for occupational exposure to
asbestos dropped dramatically over the past several decades.
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Year 8-hour TWA Asbestos PEL
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1971.............................. 12 f/cc
1971.............................. 5 f/cc
1972.............................. 2 f/cc
1983.............................. 0.5 f/cc \26\
1986.............................. 0.2 f/cc \27\
1994.............................. 0.1 f/cc
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In addition, on September 14, 1988, OSHA promulgated an asbestos
excursion limit of 1 f/cc over a sampling period of 30 minutes (53 FR
35610).
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\26\ U.S. Court of Appeals for the 5th Circuit invalidated this
rule on March 7, 1984, in Asbestos Information Association/North
America v. OSHA (727 F.2d 415, 1984).
\27\ OSHA added specific provisions in the construction standard
to cover unique hazards relating to asbestos abatement and
demolition jobs.
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OSHA's 1986 standards had applied to occupational exposure to both
asbestiform and nonasbestiform actinolite, tremolite, and anthophylite.
On June 8, 1992, OSHA removed the nonasbestiform types of these
minerals from the scope of its asbestos standards (57 FR 24310).
III. Asbestos Exposures in Mines
A. Where Asbestos Is Found at Mines
Asbestos exposure of miners can come from either naturally
occurring asbestos in the ore or host rock or from asbestos contained
in manufactured products.
1. Metal and Nonmetal Mines
The National Institute for Occupational Safety and Health (NIOSH)
and other research organizations and scientists have noted the
occurrence of cancers and asbestosis among miners involved in the
mining and milling of commodities that contain asbestos.\28\ (See Table
IV-3.) Although asbestos is no longer mined as a commodity in the
United States, veins, pockets, or intrusions of asbestos-containing
minerals have been found in other ores in specific geographic regions,
primarily in metamorphic or igneous rock.\29\ It is possible to find
asbestos in sedimentary rock. The U.S. Geological Survey (USGS) has
reported weathering or abrasion of asbestos-bearing rock and soil, or
air transportation, to carry asbestos to sedimentary deposits.\30\
MSHA's experience is that miners may encounter asbestos during the
mining of a number of mineral commodities,\31\ such as talc, limestone
and dolomite, vermiculite, wollastonite, banded ironstone and taconite,
lizardite, and antigorite. Even if asbestos contamination is found in a
specific mineral commodity, not all mines of that commodity will
encounter asbestos and those that do may encounter it rarely. (See
Table III-1.)
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\28\ NIOSH WoRLD, 2003.
\29\ MSHA (Bank), 1980; Ross, 1978.
\30\ USGS, 1995.
\31\ Roggli et al., 2002; Selden et al., 2001; Amandus et al.,
Part I, 1987; Amandus et al., Part III, 1987; Amandus and Wheeler,
Part II, 1987; Meeker et al., 2003.
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Mining activities, such as blasting, cutting, crushing, grinding,
or simply disturbing the ore or surrounding earth may cause asbestos
fibers to become airborne.\32\ Milling may transform bulk ore
containing asbestos into respirable fibers. Asbestos tends to deposit
on workplace surfaces and accumulate during the milling process, which
is often in enclosed buildings. The use of equipment and machinery or
other activities in these locations may re-suspend the asbestos-
containing dust from these surfaces into the air. For this reason, MSHA
generally finds higher asbestos concentrations in mills than among
mobile equipment operators or in ambient environments, such as pits.
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\32\ MSHA (Bank), 1980; Amandus et al., Part I, 1987.
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Some mine operators are making an effort to avoid deposits that are
likely to contain asbestos minerals. They use knowledge of the geology
of the area, core or bulk sample analysis, and workplace examinations
(of the pit) to avoid encountering asbestos deposits, thus preventing
asbestos contamination of their process stream and final product.\33\
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\33\ GETF Report, pp. 17-18, 2003; Nolan et al., 1999.
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2. Coal Mines
MSHA is aware of only one coal formation in the United States that
contains naturally occurring asbestos; however, there is no coal mining
in this formation.\34\ The more likely exposure to asbestos in coal
mining occurs at surface operations from introduced asbestos-containing
materials (ACM).
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\34\ Brownfield et al., 1995.
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3. Asbestos-Containing Materials (ACM)
Asbestos is a component in some commercial products and may be
found as a contaminant in others. The USGS estimates that, during 2006,
manufacturers in the United States used about 2,340 metric tons (5.2
million pounds) of asbestos, primarily in roofing products and coatings
and compounds. In addition to domestic manufacturing, the United States
continues to import products that contain asbestos, primarily cement
products, such as flat cement panels, sheets, and tiles.\35\
Although manufacturers have removed the asbestos from many new
products,\36\ asbestos may still be found at mines. Asbestos-containing
building materials (ACBM), such as Transite[reg] board and reinforced
cements, could present a hazard during maintenance, construction,
remodeling, rehabilitation, or demolition projects. Asbestos in
manufactured products, such as electrical insulation, joint and packing
compounds, automotive clutch and brake linings,\37\ and fireproof
protective clothing and welding blankets, could present a hazard during
activities at the mine site that may cause a release of fibers.\38\
MSHA expects mine operators to determine whether ACM or ACBM are
present on mine property by reading the labels or Material Safety Data
Sheets (MSDS) required by the OSHA Hazard Communication Standard (29
CFR 1910.1200). The presence of asbestos at a mine indicates that there
is a potential for exposure.
B. Sampling Data and Exposure Calculations
To evaluate asbestos exposures in mines, MSHA collects personal
exposure samples. MSHA samples a miner's entire work shift using a
personal air-sampling pump and a filter-cassette assembly. This
assembly is composed of a 50-mm static-reducing, electrically
conductive, extension cowl and a 0.8 [mu]m pore size, 25-mm diameter,
mixed cellulose ester (MCE) filter. Following standard sampling
procedures, MSHA also submits blank filters for analysis.
MSHA collects a sample over the entire time the miner works; 10- to
12-hour shifts are common. The time-weighted average (TWA) PELs in
MSHA's standards, however, are based on an 8-hour workday. Regardless
of the actual shift length, MSHA calculates a full-shift concentration
as if the fibers had been collected over an 8-hour shift. For work
schedules less than or greater than 8 hours, this technique allows MSHA
to compare a miner's exposure
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directly to the 8-hour TWA PEL. MSHA calls this calculated equivalent,
8-hour TWA a ``shift-weighted average'' (SWA).
MSHA's existing sampling procedures specify using several,
typically three, filter-cassette assemblies in a consecutive series to
collect a full-shift sample. For results from both PCM and TEM
analyses, MSHA calculates the SWA exposure levels for each miner
sampled from the individual filters according to the following
formulas.
SWA = (TWA1t1 + TWA2t2 + * * * + TWAntn)/480 minutes
Where:
TWAn is the time-weighted average concentration for filter ``n''
calculated by dividing the number of fibers (f) collected on the
filter by the volume of air (cc) drawn through the filter.
tn is the duration sampled in minutes for filter ``n''.
Some commenters criticized MSHA's sampling and analytical
procedures. A few commenters believed that MSHA should develop specific
test procedures for the sampling and analysis of bulk samples for the
mining environment, as well as specific air sampling procedures. Some
commenters suggested that respirable dust sampling using a cyclone
might be a means to remove interfering dust from the sample. NIOSH
recommended that thoracic samplers be evaluated in a mining
environment. Cyclones and thoracic samplers are not included in MSHA's
existing sampling and analytical protocols for asbestos and are not
included in existing approved methods. Exposures determined using these
devices have not been correlated with the risk assessment that forms
the basis of the PELs in the final rule.
Some commenters supported MSHA's existing asbestos monitoring
protocols with emphasis on full-shift monitoring for comparison to the
PEL. Other commenters stated that MSHA's existing field sampling and
analysis methods are adequate for most mines and quarries, particularly
when no significant amount of asbestos is found.
Some commenters stated that MSHA should improve its inspection
reports by including inspection field notes; sampling location,
purpose, and procedure; as well as descriptions of the accuracy,
meaning, and limitations of the analytical results. MSHA routinely
provides the sampling and analytical results and, when requested, will
provide the additional information.
C. Summary of MSHA's Asbestos Air Sampling and Analysis Results
To assess personal exposures and present the Agency's sampling data
for January 1, 2000 through May 31, 2007, MSHA calculated an SWA
exposure for each miner from the TWA results of individual filters.
MSHA has compiled these data into a PowerPoint[reg] slide, and has
posted it, together with additional explanatory information, on MSHA's
Asbestos Single Source Page at http://www.msha.gov/asbestos/
asbestos.htm.
---------------------------------------------------------------------------
\35\ USGS (Virta), 2007.
\36\ GETF Report, pp. 12 and 15, 2003.
\37\ Lemen, 2003; Paustenbach et al., 2003.
\38\ EPA, 1986; EPA, 1993; EPA, October 2003.
---------------------------------------------------------------------------
MSHA conducted asbestos sampling at 207 mines (206 non-asbestos
metal and nonmetal mines and one coal mine) during the period January
1, 2000 through May 31, 2007. Some were sampled multiple times over the
seven and one quarter years. MSHA found 29 mines with at least one
miner exposed to an equivalent 8-hour TWA (SWA) fiber concentration
exceeding 0.1 f/cc. Out of a total of 917 SWA personal full-shift fiber
exposure sample results, 113 (12 percent) exceeded 0.1 f/cc using the
existing PCM-based analytical screening method.
Further analysis of the 113 samples with TEM confirmed asbestos
fiber exposures exceeding 0.1 f/cc in 23 of them. Using the existing
TEM-based analytical method, 3 percent of the total number of SWA
samples taken exceeded 0.1 asbestos f/cc. Five mines (two taconite, one
wollastonite, one sand and gravel, and one olivine), out of the 29
mines potentially impacted by lowering the PEL, had at least one miner
with an SWA asbestos fiber exposure exceeding 0.1 f/cc. Although MSHA
has no evidence of asbestos exposure above the new PEL in coal mines,
the Agency anticipates that some coal mines will encounter asbestos
from asbestos containing materials (ACM) brought onto mine property.
These operators may have to take corrective action. Table III-1 below
summarizes MSHA's asbestos sampling results for the period January 2000
through May 2007.
Table III-1.--Personal Exposure Samples at Mines \1\ by Commodity
[1/2000-5/2007]
----------------------------------------------------------------------------------------------------------------
Number (%) of Number (%)
Number of mines with SWA Number of Number (%) of of SWA
Commodity mines samples >0.1 f/ SWA SWA samples >0.1 samples >0.1
sampled cc by PCM samples f/cc by PCM \2\ f/cc by TEM
----------------------------------------------------------------------------------------------------------------
Rock & quarry products \3\.......... 127 11 (9%) 326 20 (6%) 2 (1%)
Vermiculite......................... 4 3 (75%) 149 13 (9%) 0
Wollastonite........................ 1 1 (100%) 18 18 (100%) 9 (50%)
Iron (taconite)..................... 15 5 (33%) 254 43 (17%) 11 (4%)
Talc................................ 12 1 (8%) 38 2 (5%) 0
Alumina \4\......................... 1 0 1 0 0
Feldspar............................ 7 0 \5\ 6 0 0
Boron............................... 2 1 (50%) 12 7 (58%) 0
Olivine............................. 2 2 (100%) 9 3 (33%) 1 (11%)
Other \6\........................... 36 \7\ 5 (14%) 104 7 (6%) 0
---------------------------------------------------------------------------
TOTAL........................... 207 \8\ 29 (14%) 917 113 (12%) 23 (3%)
----------------------------------------------------------------------------------------------------------------
\1\ Excludes data from an asbestos mine and mill closed in 2003.
\2\ MSHA uses TEM to identify asbestos on samples with results exceeding 0.1 f/cc.
\3\ Including stone, and sand and gravel mines.
\4\ 15-minute sample.
\5\ Incomplete SWA at one mine.
\6\ Coal, potash, gypsum, cement, perlite, clay, lime, mica, metal ore NOS, shale, pumice, trona, salt, gold,
and copper.
\7\ Coal, potash, gypsum, cement, and perlite. (Coal and potash exposures were due to fiber release episodes
from commercially introduced asbestos).
\8\ TEM confirmed airborne asbestos exposures exceeding 0.1 f/cc at five (2%) mines.
[[Page 11289]]
The USGS has published a series of maps showing historic asbestos
prospects and natural asbestos occurrences in the United States. The
USGS published a map covering the eastern states in 2005; the central
states in 2006; and the Rocky Mountain states in 2007. These maps
served as a guide for the investigation of possible naturally occurring
asbestos within the vicinity of mining operations. MSHA found that
stone mines and quarries are the predominate types of mining operations
in the vicinity of naturally occurring asbestos locations identified on
the maps. MSHA conducted fiber sampling at these mines to screen for
potential asbestos exposures. The results of the sampling indicated a
small degree of asbestos at some of these mining operations, but no
widespread asbestos contamination. Although not included on the USGS
maps, MSHA also surveyed two mines in El Dorado County, California.
Sampling at one of the mines resulted in two personal asbestos
exposures greater than 0.1 f/cc, confirmed by TEM analysis, and 2 to 5
percent naturally occurring asbestos in an associated bulk sample. Air
sampling at the other mine had low PCM fiber results.
D. Asbestos Take-Home Contamination
The final rule, like the proposal, does not address take-home
contamination. In making this decision, MSHA considered its enforcement
experience; comments and testimony on the proposal; as well as OSHA,
NIOSH, and EPA publications and experience.\39\ MSHA based its
determination to address asbestos take-home contamination, without
promulgating new regulatory provisions, on the following factors:
---------------------------------------------------------------------------
\39\ NIOSH (Report to Congress) September 1995.
---------------------------------------------------------------------------
There are no asbestos mines or mills currently operating
in this country and different ore bodies of the same commodity, such as
vermiculite mining, are not consistent in the presence, amount, or
dispersion of asbestiform minerals. Based on MSHA's recent enforcement
sampling, asbestos exposures in mining are low. (See Table III-1.)
The measures taken to prevent take-home contamination are
varied. Operators may choose the most effective method for eliminating
this hazard based on the unique conditions in the mine, including the
nature of the hazard. For example, in one situation providing
disposable coveralls could minimize or prevent asbestos take-home
contamination. Another situation may require on-site shower facilities
coupled with clothing changes to provide the same protection.
Existing standards (e.g., personal protection Sec. Sec.
56/57.15006; sanitation Sec. Sec. 56/57.20008, 56/57.20014, 71.400,
71.402; housekeeping Sec. Sec. 56/57.16003, 56/57.20003, 77.208;
appropriate actions Sec. Sec. 56/57.18002, 56/57.20011, 77.1713;
hazard communication 30 CFR 46, 47, and 48), together with lower PELs,
provide sufficient enforcement authority to ensure that mine operators
take adequate measures when necessary to prevent asbestos take-home
contamination.
Commenters urged MSHA to expand the rulemaking to include specific
requirements to prevent take-home contamination. NIOSH also encouraged
MSHA to adopt measures included in its 1995 Report to Congress on their
Workers' Home Contamination Study Conducted under the Workers' Family
Protection Act. Other commenters, however, supported MSHA's decision
and stated that take-home contamination requirements could not be
justified at this time.
IV. Application of OSHA's Risk Assessment to Mining
MSHA has determined that OSHA's 1986 asbestos risk assessment (51
FR 22644) is applicable to asbestos exposures in mining. In developing
this final rule, MSHA also evaluated studies published since OSHA
completed its 1986 risk assessment, and studies that specifically
focused on asbestos exposures of miners. These additional studies
corroborate OSHA's conclusions in its risk assessment.
A. Summary of OSHA's Risk Assessment
1. Cancer Mortality
In its 1986 risk assessment, OSHA estimated cancer mortality for
workers exposed to asbestos at various cumulative exposures (i.e.,
combining exposure concentration and duration of exposure). MSHA has
reproduced this data in Table IV-1. Table IV-1 shows that the estimated
mortality from asbestos-related cancer decreases significantly by
lowering exposure. This is true regardless of the type of cancer, e.g.,
lung, pleural or peritoneal mesotheliomas, or gastrointestinal.
Although excess relative risk is linear in dose, the excess mortality
rates in Table IV-1 are not.\40\
---------------------------------------------------------------------------
\40\ Nicholson, p. 53, 1983.
Table IV-1.--Estimated Asbestos-Related Cancer Mortality per 100,000 by Number of Years Exposed and Exposure
Level
----------------------------------------------------------------------------------------------------------------
Cancer mortality per 100,000 exposed
Asbestos fiber concentration (f/cc) -----------------------------------------------------------------
Lung Mesothelioma Gastrointestinal Total
----------------------------------------------------------------------------------------------------------------
1-year exposure
----------------------------------------------------------------------------------------------------------------
0.1........................................... 7.2 6.9 0.7 14.8
0.2........................................... 14.4 13.8 1.4 29.6
0.5........................................... 36.1 34.6 3.6 74.3
2.0........................................... 144 138 14.4 296.4
4.0........................................... 288 275 28.8 591.8
5.0........................................... 360 344 36.0 740.0
10.0.......................................... 715 684 71.5 1,470.5
----------------------------------------------------------------------------------------------------------------
20-year exposure
----------------------------------------------------------------------------------------------------------------
0.1........................................... 139 73 13.9 225.9
0.2........................................... 278 146 27.8 451.8
0.5........................................... 692 362 69.2 1,123.2
2.0........................................... 2,713 1,408 271.3 4,392.3
4.0........................................... 5,278 2,706 527.8 8,511.8
[[Page 11290]]
5.0........................................... 6,509 3,317 650.9 10,476.9
10.0.......................................... 12,177 6,024 1,217.7 13,996.7
----------------------------------------------------------------------------------------------------------------
45-year exposure
----------------------------------------------------------------------------------------------------------------
0.1........................................... 231 82 23.1 336.1
0.2........................................... 460 164 46.0 670.0
0.5........................................... 1,143 407 114.3 1,664.3
2.0........................................... 4,416 1,554 441.6 6,411.6
4.0........................................... 8,441 2,924 844.1 12,209.1
5.0........................................... 10,318 3,547 1,031.8 14,896.8
10.0.......................................... 18,515 6,141 1,851.5 26,507.5
----------------------------------------------------------------------------------------------------------------
Table IV-1 shows that, by lowering the PEL from 2 f/cc to 0.1 f/cc,
the risk of cancer mortality drops 95 percent from an estimated 6,411
to 336 deaths (per 100,000 workers).
2. Asbestosis
Finkelstein (1982) studied a group of 201 men who worked in a
factory in Ontario, Canada, that manufactured asbestos-cement pipe and
rock-wool insulation. Finkelstein demonstrated that there was a
relationship between cumulative asbestos exposure and confirmed
asbestosis.
Berry and Lewinsohn (1979) studied a group of 379 men who worked in
an asbestos textile factory in northern England. Berry and Lewinsohn
(1979) defined two different cohorts: Men who were first employed
before 1951, when asbestos fiber levels were estimated; and men first
employed after 1950, when asbestos fiber levels were measured. They
plotted cases of possible asbestosis to determine a dose response
curve.
OSHA stated that ``* * * the best estimates of asbestosis incidence
are derived from the Finkelstein data * * *'' (48 FR 51132). OSHA did
not rely on the values for the slope as determined by Berry and
Lewinsohn (1979). Based on Finkelstein's (1982) linear relationship for
lifetime asbestosis incidence, OSHA calculated estimates of lifetime
asbestosis incidence at five exposure levels of asbestos (i.e., 0.5, 1,
2, 5, and 10 f/cc) and published its estimate in tabular form (48 FR
51132). MSHA has reproduced OSHA's estimates in Table IV-2 below. OSHA
stated (51 FR 22646) that ``Reducing the exposure to 0.2 f/cc, a
concentration not included in Table IV-2, would result in a lifetime
incidence of asbestosis of 0.5%.''
---------------------------------------------------------------------------
\41\ Finkelstein, 1982; Berry and Lewinsohn, 1979.
Table IV-2.--Estimates of Lifetime Asbestosis Incidence \41\
----------------------------------------------------------------------------------------------------------------
Percent (%) Incidence
--------------------------------------------------------------------------
Exposure level, f/cc Berry and Lewinsohn
Finkelstein Berry and Lewinsohn (first employed after
(employed before 1951) 1950)
----------------------------------------------------------------------------------------------------------------
0.5.................................. 1.24 0.45 0.35
1.................................... 2.49 0.89 0.69
2.................................... 4.97 1.79 1.38
5.................................... 12.43 4.46 * 3.45
10................................... 24.86 8.93 6.93
Slope................................ 0.055 0.020 0.015
R \2\................................ 0.975 0.901 0.994
----------------------------------------------------------------------------------------------------------------
* Note: 1.38 in original table was a typographical error. The text (48 FR 51132) and the regression formula
indicate that 3.45 is the correct percent.
Similar to the cancer risk, Table IV-2 shows a significant
reduction in the incidence of asbestosis by lowering asbestos
exposures. MSHA calculated the incidence of asbestosis following 45
years of exposure to asbestos at a concentration of 0.1 f/cc, which
OSHA had not included in Table IV-1, to be 0.25 percent or 250 cases
per 100,000 workers. Thus, by lowering the 8-hour TWA PEL from 2 f/cc
to 0.1 f/cc, MSHA will reduce the lifetime asbestosis risk by 95
percent from an estimated 4,970 cases to 250 cases (per 100,000
workers).
B. Risk Assessment for the Mining Industry
OSHA stated in the preamble to its 1986 asbestos rule that it
excluded mining studies in its risk assessment because it believed that
risks in the asbestos mining-milling operations are lower than other
industrial operations due to differences in fiber size (51 FR 22637).
MSHA reviewed the studies OSHA used to develop its risk assessment.\42\
In addition, MSHA obtained and reviewed the latest available scientific
studies on the health
[[Page 11291]]
effects of asbestos exposure. MSHA recognizes that there are
uncertainties in any risk assessment. MSHA concluded, however, that
these studies provide further support of the significant risk of
adverse health effects following exposure to asbestos.
---------------------------------------------------------------------------
\42\ Berry and Newhouse, 1983; Dement et al., 1982; Finkelstein,
1983; Henderson and Enterline, 1979; Peto, 1980; Peto et al., 1982;
Seidman et al., 1979; Seidman, 1984; Selikoff et al., 1979; Weill et
al., 1979.
---------------------------------------------------------------------------
MSHA reviewed the mining studies described in OSHA's asbestos risk
assessment, as well as other studies that involved the exposure of
miners to asbestos. Most of these studies were conducted in Canada,
although some have been conducted in Australia, India, Italy, South
Africa, and the United States. Table IV-3 lists some of these mining
studies, in chronological order, and gives the salient features of each
study. These studies are in MSHA's rulemaking docket.
Table IV.-3--Selected Studies Involving Miners Exposed to Asbestos
------------------------------------------------------------------------
Study group, type Major finding(s) or
Author(s), year of publication of asbestos conclusion(s)
------------------------------------------------------------------------
Rossiter et al., 1972......... Canadian miners Radiographic changes
and millers, (opacities) related
Chrysotile. to age and exposure.
Becklake, 1979................ Canadian miners Weak relationship
and millers, between exposure and
Chrysotile. disease.
Gibbs and du Toit, 1979....... Canadian and Need for workplace
South African epidemiologic
miners, surveillance and
Chrysotile. environmental
programs.
Irwig et al., 1979............ South African Parenchymal
miners, Amosite radiographic
and Crocidolite. abnormalities
preventable by
reduced exposure.
McDonald and Liddell, 1979.... Canadian miners Lower risk of
and millers, mesotheliomas and
Chrysotile. lung cancer from
chrysotile than
crocidolite.
Nicholson et al., 1979........ Canadian miners Miners and millers:
and millers, at lower risk of
Chrysotile. mesotheliomas, at
risk of asbestosis
(as factory workers
and insulators), at
risk of lung cancer
(as factory
workers).
Rubino et al., Ann NY Ac Sci Italian miners, Role of individual
1979. Chrysotile. susceptibility in
appearance and
progression of
asbestosis.
Rubino et al., Br J Ind Med Italian miners, Elevated risk of lung
1979. Chrysotile. cancer.
Solomon et al., 1979.......... South African Sign of exposure to
miners, Amosite asbestos: thickened
and Crocidolite. interlobar fissures.
McDonald et al., 1980......... Canadian miners No statistically
and millers, significant
Chrysotile. increases in SMRs.
McDonald et al., 1986......... U.S. miners, A. Increased risk of
Tremolite.. mortality from
respiratory cancer.
McDonald et al., 1986......... U.S. miners, B. Increased
Tremolite. prevalence of small
opacities by
retirement age.
Cookson et al., 1986.......... Australian miners No threshold dose for
and millers, development of
Crocidolite. radiographic
abnormality.
Amandus et al., 1987.......... U.S. miners and Part I: Exposures
millers, below 1 f/cc after
Tremolite- 1977, up to 100-200
Actinolite. x higher in 1960's
and 1970's.
Amandus and Wheeler, 1987..... U.S. miners and Part II: Increased
millers, mortality from
Tremolite- nonmalignant
Actinolite. respiratory disease
and lung cancer.
Amandus et al., 1987.......... U.S. miners and Part III: Increased
millers, prevalence of
Tremolite- radiographic
Actinolite. abnormalities
associated with past
exposure.
Armstrong et al., 1988........ Australian miners Increased mortality
and millers, from mesotheliomas
Crocidolite. and lung cancer.
Enarson et al., 1988.......... Canadian miners, Increased cough,
Chrysotile. breathlessness,
abnormal lung volume
and capacity.
McDonald et al., 1988......... U.S. miners and Low exposure and no
millers, statistically
Tremolite. significant SMRs.
McDonald et al., 1993......... Canadian miners Increased SMRs for
and millers, lung cancer and
Chrysotile. mesotheliomas as
cohort aged.
Dave et al., 1996............. Indian miners and Higher exposures in
millers, surface than
Chrysotile. underground mines;
higher exposures in
mills than mines;
restrictive lung
impairment and
radiologic
parenchymal changes
more common in
millers.
McDonald et al., 1997......... Canadian miners Risk of mesotheliomas
and millers, related to geography
Chrysotile. and mineralogy of
region;
mesotheliomas caused
by amphiboles.
Nayebzadeh et al., 2001....... Canadian miners Respiratory disease
and millers, related to regional
Chrysotile. differences in fiber
concentration and
not dimension.
Ramanathan and Subramanian, Indian miners and Increased risk of
2001. millers, cancer, restrictive
Chrysotile and lung disease,
tremolite. radiologic changes,
and breathing
difficulties; more
common in milling.
Bagatin et al., 2005.......... Brazilian miners Decreased risk of non-
and millers, malignant
Chrysotile. abnormalities with
improvements in
workplace
conditions.
Nayebzadeh et al., 2006....... Canadian miners Possible use of lung
and millers, fiber concentration,
Chrysotile, especially short
Tremolite, tremolite fibers, to
Amosite. predict fibrosis
grade.
Sullivan, 2007................ U.S. miners, Increased mortality
millers, and from asbestosis,
processors, cancer of the
Tremolite. pleura, and lung
cancer that were
dose-related.
------------------------------------------------------------------------
MSHA found that many of the observations presented in these mining
studies (e.g., age of first exposure, latency, radiologic changes) are
consistent with those from the studies OSHA relied on in its risk
assessment, as well as studies of other asbestos-exposed factory and
insulation workers. MSHA concludes that exposure to asbestos, a known
human carcinogen, results in similar disease endpoints regardless of
the occupation that has been studied. Because there is evidence of
asbestos-related disease among miners, MSHA is applying the OSHA risk
assessment to the mining industry.
Some commenters stated that there is a differential health risk
related to fiber type and that OSHA's risk assessment is not adequate
or appropriate for the mining industry. The OSHA risk assessment
addresses adverse health effects from exposure to six asbestos
minerals. MSHA applies TEM analysis
[[Page 11292]]
to its PCM results to determine exposure to these same six asbestos
minerals. Exposure of miners to these asbestos minerals, at the same
concentrations and length of exposures as workers in other industries,
can be expected to result in the same disease endpoints as quantified
in OSHA's risk assessment. (See section II.C and II.D of this preamble
and chapter III of the REA.)
Some commenters also expressed concern regarding the health risks
of fibrous minerals that are not currently regulated under MSHA's
existing standards and suggested that MSHA conduct a new risk
assessment to include them. MSHA considered these comments and
determined that a new risk assessment is not necessary for this final
rule, since fibrous minerals that are not currently regulated under
MSHA's existing standards are beyond the scope of this rulemaking.
Some commenters stressed the lack of asbestos-related disease among
miners in studies conducted at gold, taconite, and talc operations
where there was asbestos contamination in the ore. In developing this
final rule, MSHA considered a number of environmental and
epidemiological studies conducted at mining operations. These studies
demonstrated adverse health effects among miners consistent with
exposure to asbestos in other workers. Researchers have found excessive
incidence of asbestos-related disease in miners at a vermiculite mining
operation.\43\ Studies of talc miners have shown excess lung cancer and
non-malignant respiratory disease.\44\ Researchers are now studying
excessive mesotheliomas among iron miners in northeastern Minnesota to
determine the source of the asbestos exposure.
---------------------------------------------------------------------------
\43\ Sullivan, 2007.
\44\ NIOSH (HETA/MHETA), 1990; NIOSH (Technical Report), 1980.
---------------------------------------------------------------------------
Section VI of this preamble contains a summary of MSHA's findings
from applying OSHA's quantitative assessment of risk to the mining
industry. MSHA's Regulatory Economic Analysis (REA) contains a more in-
depth discussion of the Agency's methodology and conclusions. MSHA
placed the REA in the rulemaking docket and posted it on the Asbestos
Single Source Page at http://www.msha.gov/asbestos/asbestos.htm. MSHA
also placed OSHA's risk assessment in its rulemaking docket.
C. Characterization of the Risk to Miners
After reviewing the evidence of adverse health effects associated
with exposure to asbestos, MSHA evaluated that evidence to ascertain
whether exposure levels currently existing in mines warrant regulatory
action. The criteria for this evaluation are established by the Federal
Mine Safety and Health Act of 1977 (Mine Act) and related court
decisions.\45\
---------------------------------------------------------------------------
\45\ Industrial Union Department, AFL-CIO v. American Petroleum
Institute, 448 U.S. 607, 100 S.Ct. 2844 (1980) (``Benzene case'')
---------------------------------------------------------------------------
Section 101(a) of the Mine Act requires MSHA `` * * * to develop,
promulgate, and revise * * * improved mandatory health or safety
standards for the protection of life and prevention of injuries in coal
or other mines.'' Further, section 101(a)(6)(A) provides that--
The Secretary, in promulgating mandatory standards dealing with
toxic materials or harmful physical agents under this subsection,
shall set standards which most adequately assure on the basis of the
best available evidence that no miner will suffer material
impairment of health or functional capacity even if such miner has
regular exposure to the hazards dealt with by such standard for the
period of his working life.
Section 101(a)(6)(A) also requires that MSHA base its health and
safety standards on ``* * * the latest available scientific data in the
field, the feasibility of the standards, and experience gained under
this and other health and safety laws.'' As discussed in section VI.B,
a 0.1 f/cc TWA PEL for asbestos is technologically and economically
feasible.
Based on court interpretations of similar language under the
Occupational Safety and Health Act, MSHA has addressed the following
three questions:
(1) Do the health effects associated with asbestos exposure
constitute a ``material impairment'' to miner health or functional
capacity? Miners exposed to asbestos are at risk of developing lung
cancer, mesotheliomas, and other cancers, as well as asbestosis and
other nonmalignant respiratory diseases.\46\ These health effects
constitute a ``material impairment of health or functional capacity.''
---------------------------------------------------------------------------
\46\ American Thoracic Society, 2004; Delpierre et al., 2002.
---------------------------------------------------------------------------
(2) Are exposed miners at significant risk of incurring any of
these material impairments? Based on OSHA's risk assessment, MSHA has
determined that a significant health risk exists for miners exposed to
asbestos at MSHA's existing 8-hour TWA PEL of 2 f/cc. Over a 45-year
working life, exposure at this level can be expected to result in a 6.4
percent incidence of cancer (lung cancer, mesotheliomas, and
gastrointestinal cancer) and a 5.0 percent incidence of asbestosis.
(3) Will this final rule substantially reduce such risks? By
lowering the 8-hour TWA PEL to 0.1 f/cc, MSHA will reduce the risk of
asbestos-related cancers from 6.4 percent to 0.34 percent and the risk
of asbestosis from 5.0 percent to 0.25 percent. MSHA considers this
reduction to be substantial.
V. Section-by-Section Analysis of Final Rule
The final rule is substantively the same as the proposed rule. To
make the standard easier to read, however, MSHA has divided the
requirements in the final standards into three paragraphs: Definitions,
Permissible Exposure Limits (PELs), and Measurement of Airborne Fiber
Concentration. For Sec. Sec. 56/57.5001(b), the metal and nonmetal
asbestos standards, MSHA designated the paragraphs (b)(1), (b)(2), and
(b)(3). For Sec. 71.702, the coal asbestos standard, MSHA designated
the paragraphs (a), (b), and (c).
A. Sec. Sec. 56/57.5001(b)(1) and 71.702(a): Definitions
The final rule, like the proposal, makes no substantive changes to
the definition of asbestos in MSHA's existing standards. MSHA's
existing definition of asbestos is consistent with the regulatory
provisions of several Federal agencies including EPA, OSHA, and CPSC,
among others. Asbestos is not a definitive mineral, but rather a
generic name for a group of minerals with specific characteristics.
MSHA's existing standards state that, ``when crushed or processed,
[asbestos] separates into flexible fibers made up of fibrils''
[Sec. Sec. 56/57.5001(b)]; and ``does not include nonfibrous or
nonasbestiform minerals'' (Sec. 71.702). Although there are many
asbestiform minerals,\47\ the term asbestos in MSHA's existing
standards and this final rule is limited to the following six: \48\
---------------------------------------------------------------------------
\47\ Leake et al., 1997; Meeker et al., 2003.
\48\ ATSDR, p.136, 2001; NIOSH Pocket Guide, 2003.
---------------------------------------------------------------------------
Chrysotile (serpentine asbestos, white asbestos).
Cummingtonite-grunerite asbestos (amosite, brown
asbestos).
Crocidolite (riebeckite asbestos, blue asbestos).
Anthophylite asbestos (asbestiform anthophyllite).
Tremolite asbestos (asbestiform tremolite).
Actinolite asbestos (asbestiform actinolite).
Like the proposal, the final rule makes several clarifying changes
to the existing regulatory language. They have no impact on the
minerals that MSHA regulates as asbestos. This more precise
[[Page 11293]]
language will facilitate mine operators' understanding of the scope of
the standard. This final asbestos rule--
Clarifies that cummingtonite-grunerite asbestos is the
mineralogical term for amosite, a trade name for asbestos from a
specific geographical region;
Clarifies that MSHA's definition of fiber for analytical
purposes includes the same dimensional criteria as in the existing
standards, which are consistent with OSHA's asbestos standard; and
Clarifies the asbestos standard by inserting uniform
structure and language.
Some commenters suggested that MSHA should expand its definition of
asbestos to include other asbestiform minerals, so long as MSHA's
analytical method excluded the counting of cleavage fragments. Another
commenter asked that MSHA not include nonasbestiform fibrous minerals
and mineral cleavage fragments when MSHA performs microscopic analyses
of samples. Others supported the inclusion and regulation of
asbestiform amphiboles that have shown or are likely to show asbestos-
like health effects.
Many commenters did not want MSHA to make changes to the fibers
regulated as asbestos in the existing standards. Specifically, they did
not want MSHA to address other asbestiform amphiboles found in mineral
deposits because there is no evidence that these fibers pose the same
health problems that asbestos does. Some said that it would be
unreasonable and expensive to try to meet exposure limits for all these
other asbestiform minerals. Other commenters stated that, whatever they
are called, asbestiform minerals cause illness.
As stated throughout this rulemaking, the final rule makes no
substantive changes to the definition of asbestos in MSHA's existing
standards. Such changes were not contemplated in the proposed rule and,
therefore, are beyond the scope of this final rule.
B. Sections 56/57.5001(b)(2) and 71.702(b): Permissible Exposure Limits
(PELs)
1. Sections 56/57.5001(b)(2)(i) and 71.702(b)(1): 8-Hour, Time-Weighted
Average (TWA), Full-Shift Permissible Exposure Limit
The final rule adopts OSHA's 8-hour TWA PEL of 0.1 f/cc. No
commenters objected to this aspect of the proposal.
Asbestos occurs naturally in many types of ore bodies and may be
released from mine sites into the environment; but, MSHA's sampling
results indicate that there is not widespread overexposure to asbestos
in the mining industry at this time. MSHA's sampling data for 2000
through May 2007 show that 3 percent of MSHA's full-shift asbestos
samples exceed OSHA's TWA PEL of 0.1 f/cc using a TEM-based analysis.
Commenters expressed concern about potential asbestos exposure of
those living close to a mining operation. Although MSHA's reduction of
its asbestos PELs may reduce environmental levels, other Federal,
State, and local agencies have jurisdiction over environmental
exposures.
2. Sections 56/57.5001(b)(2)(ii) and 71.702(b)(2): Excursion Limit
The final rule, like the proposal, adopts OSHA's excursion PEL of 1
f/cc as measured over 30 minutes. Some commenters were concerned that
an excursion limit is not enforceable and, therefore, should be removed
from the rule. Although MSHA may not always be present to take air
samples to evaluate a miner's exposure during brief episodes of
asbestos exposure, existing Sec. Sec. 56/57.5002 and 71.701 require
mine operators to conduct sampling to determine the need for, and
effectiveness of, control measures when miners may be exposed to
asbestos.
An excursion limit sets levels, not based on toxicological data,
for peak episodes of exposure. As previously discussed, asbestos poses
a long-term health risk to exposed workers. Although the final rule
will substantially reduce the risk of asbestos-related deaths from a
lifetime exposure, it does not completely eliminate this risk. The
excursion limit will help reduce the long-term risk by addressing
brief, episodic exposures. This type of episodic exposure can be
foreseen and proactively controlled by the use of personal protective
equipment (respirators and protective clothing) and by implementing
engineering or work practice controls (glove boxes, tents, wet
methods).
The final rule includes an excursion limit for asbestos to help
maintain the average airborne concentration below the full-shift
exposure limit. For example, for miners exposed to one 30-minute
excursion per day at 1 f/cc, the 8-hour TWA airborne asbestos
concentration would be 0.06 f/cc, which is less than the 0.1 f/cc 8-
hour TWA PEL. For miners exposed to two 30-minute excursions per day at
1 f/cc, the 8-hour TWA airborne asbestos concentration would be 0.13 f/
cc, which exceeds the 0.1 f/cc 8-hour TWA PEL.
One commenter urged MSHA to retain 15 minutes, rather than switch
to 30 minutes, as the sampling period for enforcement of the excursion
limit. As shown in Table V-1 below, the excursion limit of 1 f/cc for
30 minutes is the lowest concentration that MSHA can measure reliably
for determining compliance with the excursion limit. MSHA recognizes
that in some situations, such as low background dust levels, lower
exposures could be measured by using a higher flow rate; but, the risk
of overloading the filter with debris increases when using higher flow
rates. MSHA can be confident that it is measuring the actual airborne
concentrations of asbestos, within a standard sampling and analytical
error (25 percent), when the Agency uses the minimum
loading suggested by the OSHA Reference Method (29 CFR 1910.1001,
Appendix A).
As discussed in OSHA's 1986 asbestos final rule (51 FR 22686), the
key factor in sampling precision is fiber loading. To determine whether
the analytical method described in Appendix A of its asbestos standard
could be used to analyze short-term samples, OSHA calculated the lowest
reliable limit of quantification using the following formula:
C = [(f/[(n)(Af)])(Ac)]/[(V)(1,000)]
Where:
C = fiber concentration (in f/cc of air);
f = the total fiber count;
n = the number of microscope fields examined;
Af = the field area (0.00785 mm2) for a
properly calibrated Walton-Beckett graticule;
Ac = the effective area of the filter (in
mm2); and
V = the sample volume (liters).
Table V-1 was generated from the above equation. The table shows
that 1 f/cc measured over 30 minutes can be reliably measured when
pumps are used at the higher flow rates of 1.6 Lpm or more, using 25-mm
filters. The table also shows that MSHA cannot reliably measure 1 f/cc
with 15-minute air samples, even when they are collected at the higher
pump flow rates.
[[Page 11294]]
Table V-1.--Relationship of Sampling Method to Measurement of Asbestos
------------------------------------------------------------------------
Lowest level reliably
Sampling time and flow rate measured using 25-mm
filters
------------------------------------------------------------------------
15 min at 2.5 Lpm.......................... 1.05 f/cc.
15 min at 2.0 Lpm.......................... 1.31 f/cc.
15 min at 1.6 Lpm.......................... 1.63 f/cc.
15 min at 1.0 Lpm.......................... 2.61 f/cc.
15 min at 0.5 Lpm.......................... 5.23 f/cc.
30 min at 2.5 Lpm.......................... 0.51 f/cc.
30 min at 2.0 Lpm.......................... 0.65 f/cc.
30 min at 1.6 Lpm.......................... 0.82 f/cc.
30 min at 1.0 Lpm.......................... 1.31 f/cc.
30 min at 0.5 Lpm.......................... 2.61 f/cc.
------------------------------------------------------------------------
After evaluating the comments, MSHA retains the proposed asbestos
excursion limit of 1 f/cc over a period of 30 minutes in the final
rule.
C. Sections 56/57.5001(b)(3) and 71.702(c): Measurement of Airborne
Fiber Concentrations
The final rule, like the proposed rule, requires an initial
determination of fiber concentration using a PCM-based analytical
method statistically equivalent to the OSHA Reference Method in OSHA's
asbestos standard (29 CFR 1910.1001, Appendix A).
With respect to analytical methods, the final rule is substantively
the same as MSHA's existing standards. PCM-based analytical methods
were used in the development of past exposure assessments and risk
estimates, and are relatively quick and cost-effective. OSHA used a
PCM-based methodology as the defining basis of its asbestos risk
assessment. PCM-based analytical methods remain the most practical way
to evaluate asbestos exposures in mining. MSHA recognizes, however,
that all analytical methods, including those used to identify and
quantify the six asbestos minerals regulated by MSHA have limitations.
Analysts have quantified the limits of detection, precision, and
accuracy of these methods, termed ``analytical error;'' and MSHA
includes this analytical error in evaluating asbestos exposures and
enforcing the PELs. As discussed below, comments varied on MSHA's
proposed sampling and analytical techniques. Most commenters supported
a combination of PCM-based and TEM-based techniques for evaluating mine
air samples.
1. Background of Analytical Method for Asbestos
Historically, asbestos samples have been analyzed by mass
(weighing), counting (microscopy), or a qualitative property
(spectroscopy). When recommending an exposure standard for chrysotile
asbestos, the British Occupational Hygiene Society said \49\ that the
microscopic counting of particles greater than 5 [mu]m in length would
show a relationship with the prevalence of asbestosis similar to those
studies based on the mass of respirable asbestos. Many studies have
suggested that counting only fibers longer than 5 [mu]m minimizes
variations between microscopy techniques \50\ and improves the
precision of the results.\51\ The scientific community accepted this
length together with a minimum 3:1 length to diameter aspect ratio, as
the counting criteria for asbestos fibers that provides an index of
asbestos exposure, even though some believed that shorter fibers should
be included due to their possible health effects.\52\ Acceptance of
PCM-based methodology has served as the basis of asbestos risk
assessments.
---------------------------------------------------------------------------
\49\ Lane et al., 1968.
\50\ ACGIH-AIHA, 1975.
\51\ Wylie, 2000.
\52\ ACGIH-AIHA, 1975; NIOSH, 1972.
---------------------------------------------------------------------------
In recommending an asbestos standard in 1972 and 1976, NIOSH
suggested using the same size criteria that the British adopted. They
also recommended reevaluating these criteria when more definitive
information on the biologic response and precise epidemiologic data are
developed. NIOSH applied a conversion factor to exposure data not
obtained using a PCM-based analytical method, to estimate what the
exposure data would have been using a PCM-based method. This conversion
allowed NIOSH to use non-PCM-based exposure data, together with PCM-
based exposure data, in determining a recommended permissible exposure
level.
2. MSHA's Analytical Methods for Enforcement of Its Asbestos PELs
Prior to 2001, OSHA analyzed MSHA's asbestos samples using OSHA ID-
160, a PCM-based analytical method. Since 2001, MSHA has contracted
with American Industrial Hygiene Association (AIHA) accredited
laboratories to analyze its asbestos samples using NIOSH's PCM-based
analytical method, and to follow up with an analysis using NIOSH's TEM-
based method when the PCM results indicate an exposure exceeding 0.1 f/
cc. These commercial laboratories report analytical results as the
fiber concentration (f/cc) for each filter analyzed.
Several factors complicate the evaluation of personal exposure
levels in mining environments. For example, non-asbestos fibers and
dust particles collected on the filter can obscure the asbestos fibers
or overload the filter. Depending on the amount of visible dust in the
air, MSHA's sampling procedures allow the setting of pump flow rates
and consecutive sampling to minimize or eliminate mixed dust overload.
Commenters criticized MSHA's use of PCM-based methods to evaluate
asbestos exposures. Several recommended that MSHA adopt a new ASTM
method (ASTM D 7200-06), which references the characteristics of
asbestiform fibers in EPA's bulk sample method.\53\ Many recommended
that MSHA not conduct air sampling unless prior bulk sampling had
identified asbestos fibers. Some commenters recommended that the final
rule include a TEM-based analytical method for the initial
determination of compliance.
---------------------------------------------------------------------------
\53\ ASTM, 2006; EPA, 1993.
---------------------------------------------------------------------------
Bulk sampling presents limitations. The presence of asbestos in a
bulk sample does not mean that it poses a hazard. The asbestos must
become airborne and be respirable, or contaminate food or water, to
pose a health hazard to miners. Analysis of bulk samples is usually
performed using polarized light microscopy (PLM). A particle must be at
least 0.5 [mu]m in diameter to refract light and many asbestos fibers
are too thin to refract light. Asbestos may be a small percentage of
the parent material or not uniformly dispersed in the sample and,
[[Page 11295]]
therefore, may not be seen in the small portion of sample that is
examined under the microscope. Another problem with identifying
asbestos using PLM is that both the asbestiform and nonasbestiform
varieties of a mineral show the same refractive index. Although a
trained individual may be able to identify bulk asbestos by its
appearance and physical properties, the identification can be difficult
when the asbestos is dispersed in a dust sample or is present in low
concentration in a rock.
Due to a lack of consensus in the regulatory and scientific
communities, revisions to MSHA's use of PCM-based analytical methods
were not included within the scope of this rulemaking. If PCM-based
analysis reveals a potential overexposure, MSHA will perform a TEM-
based analysis to confirm asbestos exposure levels. Further, MSHA will
consider the use of alternative analytical methods for the measurement
of airborne asbestos that meet the analytical equivalency criteria for
OSHA's Reference Method once they are recognized by a laboratory
accreditation organization. For example, NIOSH is supporting an ASTM
inter-laboratory study to validate whether ASTM D7200-06, ``Standard
Practice for Sampling and Counting Airborne Fibers, Including Asbestos
Fibers, in Mines and Quarries, by Phase Contrast Microscopy and
Transmission Electron Microscopy'' can meet the OSHA equivalency
criteria and be accredited.
a. Discussion of Microscope Properties.
One issue commenters mentioned concerning PCM-based analytical
methods is the limited resolution and magnification of light
microscopes compared to electron microscopes. The resolution of the
microscope is the smallest separation between two objects that will
allow them to be distinctly visible. The higher the resolving power of
a microscope, the smaller the distance can be between two particles and
have them still appear as two distinct particles. Resolution is about
0.2 [mu]m using PCM compared with 0.0002 [mu]m using TEM. This means
that an analyst who sees a single fiber using PCM may see a number of
thinner fibers using TEM. Individual fibrils of chrysotile are about
0.05 [mu]m in diameter while amphibole fibrils are about 0.1 [mu]m in
diameter. Using TEM, the analyst is able to see thinner fibers and,
therefore, should be able to see more fibers than when using PCM.
Magnification is the ratio of the size that the object appears
under the microscope to its actual size. A PCM-based analysis of air
samples for asbestos typically uses a magnification of 400 to 450 times
(x) the object's actual size. In contrast, a TEM-based analysis
typically uses a magnification of 10,000x. As a result, an analyst
using PCM sees a larger amount of the sample than one using TEM,
although in less detail.
b. Variability in Counting Asbestos Fibers Using PCM.
Commenters generally supported MSHA's use of a PCM-based analytical
method for the initial analysis of fiber samples for determining
compliance. One of the commenters' major concerns focused on the
variability of fiber counting procedures. MSHA understands that the
PCM-based analytical methods yield considerable variability in counting
fibers because it is dependent on a number of related variables, such
as the optical performance of the microscope, the optical properties of
the prepared sample, and the proportion of fine particles.\54\
---------------------------------------------------------------------------
\54\ Rooker et al., 1982.
---------------------------------------------------------------------------
OSHA recognized the variability of using a PCM-based analytical
method in its rulemaking. The requirements listed at 29 CFR 1910.1001
Appendix A minimize the effect of the known variability by describing
the essential steps of a generic sampling and analytical procedure.
OSHA also established criteria to limit variability. Subsequently,
other papers have addressed variability issues related to PCM counting
techniques.\55\
---------------------------------------------------------------------------
\55\ Pang, 2000; Harper and Bartolucci, 2003.
---------------------------------------------------------------------------
Commenters suggested a number of techniques to reduce the
variability in counting fibers on mine air samples. Some asked that
MSHA consider respirable or thoracic sampling to minimize interference
from large particles that can obscure asbestos fibers on the filter.
Some supported a counting technique based on the typical
characteristics of asbestos in air. Others recommended using a higher
aspect ratio to increase the probability that the structures counted
are fibers. Another commenter stated that several approaches have been
tried to remove non-asbestos minerals from samples, such as low
temperature ashing or dissolution, but these approaches are not useful
for mining samples. Many commenters suggested the development of
differential counting techniques that consider the fiber morphology and
the distributions or populations of distinct fiber groups with
characteristic dimensions to analyze mine air samples for fibers. Other
commenters stated that particle characteristics could not be used
reliably to differentiate fibers from cleavage fragments when examining
relatively small numbers of fibers. Several commenters suggested the
development of a new analytical method for asbestos in mine air
samples.
Much of the variability in counting asbestos is attributed to the
visual acuity of the analyst in observing and sizing fibers and in
interpreting the counting rules.\56\ Overall, commenters recognized
that it takes far less time to develop expertise in counting fibers
using PCM than in developing expertise using TEM. NIOSH has developed a
40-hour training course for analysts as an adequate prerequisite to
conducting total fiber counts using PCM. To differentially count
asbestos fibers, an analyst must have advanced knowledge of mineralogy
and expertise in the microscopic techniques used. This knowledge and
expertise can be gained only by years of experience counting fiber
samples collected in a variety of environments.
---------------------------------------------------------------------------
\56\ Rooker et al., 1982.
---------------------------------------------------------------------------
The availability of analyst training courses, and the formation of
accreditation bodies requiring laboratory quality assurance programs,
helps minimize the variations in measurements between and within
laboratories.\57\ Accreditation bodies require laboratories to use
standardized analytical methods. AIHA has the Asbestos Analyst Registry
that specifies criteria for competence, education, and performance for
analysts. In addition to these programs, MSHA's incorporation of OSHA's
Appendix A helps minimize the subjectivity and increase consistency of
measuring airborne asbestos concentrations by specifying core elements
of an acceptable PCM-based analytical method.
---------------------------------------------------------------------------
\57\ Schlect and Shulman, 1995.
---------------------------------------------------------------------------
3. MSHA's Incorporation of Appendix A of OSHA's Asbestos Standard
MSHA's existing standards include basic elements of PCM-based
analytical methods. These same basic elements for asbestos exposure
monitoring are included in the OSHA Reference Method in Appendix A of
OSHA's asbestos standard. The evaluation or inclusion of methods that
do not include these basic elements or that deviate from the criteria
for counting fibers in MSHA's existing standards was not contemplated
in the proposed rule and, therefore, is beyond the scope of this final
rule.
OSHA's Appendix A, the OSHA Reference Method (ORM), specifies the
elements of an acceptable analytical method for asbestos and the
quality
[[Page 11296]]
control procedures that laboratories performing the analysis must
implement. To encourage innovation and technological advancement, the
final rule allows for MSHA's acceptance of other analytical methods
that are at least as effective in identifying potential asbestos
overexposures as the OSHA Reference Method (29 CFR 1910.1001, Appendix
A). MSHA considers the counting criteria for a fiber in the OSHA
Reference Method to be statistically equivalent to that in MSHA's
definition of a fiber.
For the purpose of this final rule, MSHA considers a method to be
statistically equivalent to the ORM and at least as effective as MSHA's
existing method if it meets the following criteria from 29 CFR
1910.1001(d)(6)(iii):
(A) Replicate exposure data used to establish equivalency are
collected in side-by-side field and laboratory comparisons; and
(B) The comparison indicates that 90% of the samples collected
in the range 0.5 to 2.0 times the permissible limit have an accuracy
range of plus or minus 25 percent of the ORM results at a 95%
confidence level as demonstrated by a statistically valid protocol;
and
(C) The equivalent method is documented and the results of the
comparison testing are maintained.
Although MSHA can calculate concentrations below 0.1 f/cc, neither
NIOSH 7400 nor OSHA ID 160 sampling and analytical methods obtain
statistically reliable, repeatable measurements within 25
percent of the mean with 95 percent confidence for concentrations lower
than 0.1 f/cc. The preamble to OSHA's 1994 asbestos rule (59 FR 40967)
states that 0.1 f/cc is ``the practical lower limit of feasibility for
measuring asbestos levels reliably.''
Appendix A lists NIOSH 7400 and OSHA ID-160 as analytical methods
that meet these equivalency criteria. MSHA will consider other
analytical methods that afford an equivalent measurement alternative as
they become available.
4. Epidemiological Studies and Health Risk Data Based on PCM Analytical
Methods
A number of commenters pointed out that a PCM-based methodology
counts more than asbestos. These commenters suggested that the lower
risk seen in epidemiological studies relating PCM-based exposure
estimates to adverse health outcomes in miners was due to the other
material inherent in air samples taken in a mining environment. They
speculated that non-asbestos dust particles had been counted and
included in the estimated concentrations, which would have
overestimated asbestos exposures. MSHA acknowledges the possible
overestimation of asbestos-related disease in applying OSHA's risk
assessment to mining exposures based solely on PCM analytical results.
For this reason, by policy, MSHA uses a subsequent TEM analysis to
identify asbestos minerals and minimize this overestimation when
determining asbestos exposures. MSHA has not found sufficient
information to make a ``differential risk'' determination for the
mining industry within OSHA's quantitative risk assessment, which MSHA
uses as the basis for this final rule.
5. Discussion of Cleavage Fragments and Non-Asbestos Minerals
During this rulemaking, MSHA has received many comments regarding
cleavage fragments. MSHA has not addressed cleavage fragments in this
final rule. To do so would require a change in both the analytical
method and the definition of asbestos, neither of which were
contemplated in the proposed rule and are, therefore, beyond the scope
of this final rule. The final rule retains MSHA's PCM-based analytical
method. To minimize the impact of cleavage fragments on sampling
results, however, MSHA will continue its policy of conducting a
subsequent TEM-based analysis on samples with PCM results that exceed
the PEL.
Many commenters expressed concern that standard phase contrast
counting techniques are not specific in determining exposure to only
the six Federal asbestos minerals and may misidentify cleavage
fragments as asbestos fibers. PCM-based analytical methods do not
distinguish between asbestos and any other fiber meeting the size and
aspect ratio criteria. A number of commenters highlighted the seeming
contradiction between MSHA's stated intent to exclude cleavage
fragments from the standard and the Agency's selection of a PCM-based
analytical method that may identify elongated amphibole cleavage
fragments as asbestos fibers.
Commenters suggested several ways to eliminate cleavage fragments.
For example, some suggested that MSHA use a revised PCM-based method
with differential counting criteria that referenced OSHA's 29 CFR
1910.1001 Appendices B and C.\58\ Others suggested a proposed ASTM
method, which was adopted in June 2006 (ASTM D 7200-06). Several
recommended a fiber population analysis that examined samples for the
characteristics of commercial asbestos listed in Appendix A of EPA's
Method for the Determination of Asbestos in Bulk Building Materials
(EPA, 1993).
---------------------------------------------------------------------------
\58\ Appendix B (non-mandatory) is a detailed procedure for
asbestos sampling and analysis. OSHA removed Appendix C (mandatory),
which specified qualitative and quantitative fit testing procedures,
when they promulgated their respiratory protection standard (29 CFR
1910.134). Given the context of the comment, MSHA thinks the
commenter may have been referring to Appendix J, OSHA's PLM
analytical method.
---------------------------------------------------------------------------
MSHA acknowledges that PCM-based analytical methods for the
quantitative analysis of asbestos samples have some limitations,
especially if samples are collected in a mixed dust environment. PCM-
based analysis, however, addresses the key problem of needing to make a
relatively fast, cost-effective evaluation of miners' work environments
so as to improve their health protection. Using a PCM-based analytical
method maintains the usefulness of the analytical results relative to
the historic health data.\59\ When an exposure exceeds the full-shift
or excursion PEL, MSHA uses a TEM-based method to confirm the presence
of asbestos.
---------------------------------------------------------------------------
\59\ Wylie et al., 1985.
---------------------------------------------------------------------------
D. Sec. 71.701(c) and (d): Sampling; General Requirements (Controlling
Asbestos Exposures in Coal Mines)
This final rule retains the proposed revision to add a reference to
Sec. 71.702 in paragraphs (c) and (d) of Sec. 71.701 to clarify
MSHA's intent that coal mine operators control miners' exposures to
asbestos. MSHA received no substantive comments on this proposed
change.
VI. Regulatory Analyses
A. Executive Order (E.O.) 12866
Executive Order (E.O.) 12866 (58 FR 51735) as amended by E.O. 13258
(Amending Executive Order 12866 on Regulatory Planning and Review (67
FR 9385)) requires regulatory agencies to assess both the costs and
benefits of regulations. To comply with Executive Order 12866, MSHA has
prepared a Regulatory Economic Analysis (REA) for this final rule. The
REA contains supporting data and explanation for the summary materials
presented in section VI of this preamble, including the covered mining
industry, costs and benefits, feasibility, and small business impact.
The REA is located on MSHA's Web site at http://www.msha.gov/
regsinfo.htm. A copy of the REA can be obtained from MSHA's Office of
Standards, Regulations, and Variances.
Executive Order 12866 classifies a rule as a significant regulatory
action
[[Page 11297]]
requiring review by the Office of Management and Budget if it has an
annual effect on the economy of $100 million or more; creates a serious
inconsistency or interferes with an action of another agency;
materially alters the budgetary impact of entitlements or the rights of
entitlement recipients; or raises novel legal or policy issues. MSHA
has determined that the final rule would not have an annual effect of
$100 million or more on the economy and, therefore, it is not an
economically ``significant regulatory action'' pursuant to section 3(f)
of E.O. 12866. MSHA, however, has concluded that the proposed rule is
otherwise significant under Executive Order 12866 because it raises
novel legal or policy issues.
1. Discussion of Benefits
This final rule will reduce diseases arising from exposure to
asbestos, and the associated costs to employers, miners' families, and
society at large. Exposure to asbestos can cause lung cancer;
mesothelioma; gastrointestinal cancer; cancers of the larynx, pharynx,
and kidneys; asbestosis; and other respiratory diseases. Reduced
miners' exposures will reduce adverse health effects both in terms of
the incidence of disease affecting quality of life, and deaths from
both cancer and non-cancer disease. These asbestos-related diseases
cause a material impairment of human health or functional capacity.
This benefit analysis quantifies the reduction in expected deaths
to miners resulting from reduced exposure to airborne asbestos. The
benefit is a result of reducing the 8-hour time-weighted average (TWA)
permissible exposure limit (PEL) from 2 fibers per cubic centimeter (f/
cc) to 0.1 f/cc. MSHA acknowledges that this change will not eliminate
the risk of asbestos-related material impairment of health. (See Table
IV-1.)
a. Summary of Benefits.
By lowering the PEL to 0.1 f/cc, MSHA estimates the prevention of
one occupationally related cancer death caused by asbestos exposure
over the 55-year period beginning 10 years after implementation of the
final rule. MSHA estimates that there will be benefits resulting from
lowering the excursion limit, but is unable to quantify these benefits.
This analysis underestimates the total benefits of the rule by
quantifying only the cancer deaths prevented. The benefits do not
include the reduced incidence of asbestosis-related disabilities.
b. Calculation of Premature Deaths Prevented.
MSHA limits the quantified benefits to an estimation of the number
of cancer cases prevented. MSHA expresses the results as ``deaths
prevented'' because the cancers associated with asbestos exposure
almost always result in premature death.
The benefits resulting from a reduction in the PEL depend on
several factors including--
Existing and projected exposure levels,
Risk associated with each exposure level,
Number of workers exposed at each exposure level, and
Age of the miner at first exposure.
MSHA estimated the number of miners currently exposed and their levels
of exposure from data on personal exposure sampling during regular and
special inspections between January 2000 and May 2007. These data are
available on MSHA's Web site at http://www.msha.gov. Section III of
this preamble contains the characterization and assessment of exposures
in mining.
Laboratory results indicate that exposure concentrations are
unevenly distributed across mines and among miners within mines. MSHA
uses four fiber concentration levels to estimate the risk to miners.
The break points for these exposure levels are the existing and final
exposure limits as follows: Less than 0.1 f/cc, 0.1 to less than 1 f/
cc, 1 f/cc to less than 2 f/cc, and 2 f/cc or greater. Approximately 86
percent of MSHA's PCM-based fiber sampling results are below 0.1 f/cc.
Approximately 97 percent of MSHA's TEM-based asbestos sampling results
are below 0.1 f/cc. Based on MSHA's sampling data, concentrations
ranged between 0.0 and 38.1 f/cc over these years. The highest
concentration level in Table IV-1 is 10 f/cc. MSHA's calculations,
therefore, use an upper exposure limit of 10 f/cc. Samples with
exposure concentrations above 10 f/cc are included in this benefits
analysis as 10 f/cc. MSHA's estimated benefits derive totally from the
mines MSHA has sampled.
MSHA applied OSHA's linear, no-threshold, dose-response risk
assessment model to MSHA's existing PEL and final PEL to estimate the
expected number of asbestos-related deaths. The expected reduction of
deaths resulting from lowering the PEL will be the difference between
the expected deaths at 2 f/cc and 0.1 f/cc.\60\ MSHA then applied these
rates to the estimated number of miners exposed at the corresponding
concentration based on MSHA sampling data. The result is an estimate of
miners' deaths resulting from cancer due to occupational exposure to
asbestos under existing exposure conditions.
---------------------------------------------------------------------------
\60\ Nicholson, 1983; JRB Associates, 1983; OSHA (51 FR 22612),
1986; OSHA (53 FR 35609), 1988; OSHA (59 FR 40964), 1994.
---------------------------------------------------------------------------
c. Benefits of the 0.1 f/cc PEL.
Deaths from lung cancer, mesotheliomas, gastrointestinal cancer,
and asbestosis are the result of past exposures to much higher air
concentrations of asbestos than those found in mines today. The risks
of these diseases still exist, however, and these risks are significant
for miners exposed to lower air concentrations of asbestos. Most
diseases resulting from a more recent asbestos exposure may not become
evident for another 20 to 30 years. When the results of TEM analysis
are incorporated into the exposure data, MSHA estimated a reduction of
one cancer death (per 314 miners exposed above 0.1 f/cc, or 5 per 1,000
exposed) over a 55-year period starting 10 years after implementation
of the lower 8-hour TWA PEL. This represents a 12 percent reduction in
the miners' asbestos-related deaths that would be expected if existing
exposures were to continue. The rate at which the incidence of the
cancers decreases depends on several factors including--
Latency of onset of cancer,
Attrition of the mining workforce,
Changing rates of competing causes of death,
Dynamics of other risk factors,
Changes in life expectancy, and
Advances in cancer treatments.
d. Benefits of the 1 f/cc Excursion Limit.
The intended effect of the excursion limit is to protect miners
from the adverse health risks associated with brief fiber releases.
MSHA believes that miners will be exposed to brief fiber releases even
when airborne concentrations of asbestos do not exceed the PEL. For
example, mechanics may be inadvertently exposed to airborne asbestos
while working on older equipment that may have asbestos-containing
parts. Miners may encounter brief fiber releases while drilling,
dozing, blasting, or roof bolting in areas of naturally occurring
asbestos. These short-term exposures can easily be above 1 f/cc;
however, when averaged over an 8-hour shift, they fall within the 0.1
f/cc PEL. However, because MSHA does not have sufficient data regarding
the relationship between the frequency of brief fiber releases and
adverse health risks, this analysis demonstrates the theoretical
benefits from limiting short-term exposures to the excursion limit.
This section estimates the benefits of the excursion limit of 1 f/
cc for one 30-
[[Page 11298]]
minute period per day. Two 30-minute exposures per day at 1 f/cc will
exceed the 8-hour TWA, full shift exposure limit (i.e., 1 f/cc for 48
minutes = 0.1 f/cc for 480 minutes).
MSHA estimates the benefit of an excursion limit from the
difference in concentration between the PEL and the excursion limit
averaged over the full shift [(1 f/cc)/(16 30-minute periods) = 0.063
f/cc]. The lifetime risk associated with an exposure to 0.1 f/cc is
0.00336, if first exposed at age 25 and exposure continues every work
day at that level for 45 years. The risk associated with exposure to
0.063 f/cc using the same age and duration of exposure is 0.00212. The
difference in lifetime risk is 0.00124, which equates to one additional
premature death prevented for every 1,000 miners exposed to asbestos
above the 1 f/cc excursion limit.
2. Discussion of Costs
The final rule will result in total costs of approximately $201,000
per year for all mines. The cost will be approximately $156,000 for
metal and nonmetal mines and approximately $45,000 for coal mines.
These costs represent less than 0.001 percent of the yearly revenues of
$64.4 billion for the metal and nonmetal mining industry and $27.0
billion for the coal mining industry.
Table VI-1 presents MSHA's estimate of the total yearly compliance
costs by compliance strategy and mine size. The total costs reported
are projected costs, in 2006 dollars, based on MSHA's knowledge,
experience, and available information.
Table VI-1.--Summary of Yearly Compliance Costs
----------------------------------------------------------------------------------------------------------------
Compliance strategy
---------------------------------------------------------------- Total for
Metal and nonmetal mine size Selective metal and
mining Wet methods Ventilation Removal of ACM nonmetal mines
----------------------------------------------------------------------------------------------------------------
1-19............................ $2,417 $2,820 $1,619 $1,750 $8,606
20-500.......................... 11,242 19,673 28,048 21,000 79,962
501+............................ 3,747 6,558 41,278 15,750 67,333
Total....................... 17,406 29,050 70,945 38,500 155,901
----------------------------------------------------------------------------------------------------------------
Compliance strategy
---------------------------------------------------------------- Total for coal
Coal mine size Selective mines
mining Wet methods Ventilation Removal of ACM
----------------------------------------------------------------------------------------------------------------
1-19............................ .............. .............. .............. $875 $875
20-500.......................... .............. .............. .............. 12,250 12,250
501+............................ .............. .............. .............. 31,500 31,500
Total....................... .............. .............. .............. 44,625 44,625
----------------------------------------------------------------------------------------------------------------
B. Feasibility
MSHA has determined that the requirements of this final rule are
both technologically and economically feasible.
In the discussion of PELs in section V.B of this preamble, MSHA
stated that there is a residual risk of adverse health effects for
miners exposed at the PEL. MSHA considered proposing a lower PEL as a
regulatory alternative to further reduce the risk of adverse health
effects from a working lifetime of exposure. When OSHA reduced the PEL
from 0.2 to 0.1 f/cc in 1994, OSHA concluded that this concentration is
``the practical lower limit of feasibility for measuring asbestos
levels reliably.'' (59 FR 40967) About 85 percent of the sampled mines
are already in compliance with the 0.1 f/cc PEL.
This final rule is not a technology-forcing standard. All equipment
required by the final rule and a variety of dust control strategies and
control methods are already available in the marketplace and have been
used successfully by the U.S. mining community to control asbestos
exposures. MSHA has concluded that this final rule is technologically
feasible.
The mining industry would incur costs of about $201,000 yearly to
comply with this final rule. These compliance costs represent less than
0.001 percent of the yearly revenues of the mines covered by this rule
(approximately $64.4 billion for metal and nonmetal and $27.0 billion
for coal). MSHA has concluded that this final rule is economically
feasible.
D. Regulatory Flexibility Analysis (RFA) and Small Business Regulatory
Enforcement Fairness Act (SBREFA)
Based on MSHA's data and experience, and information submitted to
the record, the Agency has determined and here certifies that this
final rule will not have a significant economic impact on a substantial
number of small entities. The REA for this final rule (RIN: 1219-AB24),
Asbestos Exposure Limit, contains the factual basis for this
certification as well as complete details about data, equations, and
methods used to calculate the costs and benefits. MSHA has placed the
REA in the rulemaking docket and posted it on MSHA's Web site at http:/
/www.msha.gov.
E. Other Regulatory Considerations
1. The National Environmental Policy Act of 1969 (NEPA)
MSHA has reviewed the final rule in accordance with the
requirements of NEPA of 1969 (42 U.S.C. 4321 et seq.), the regulations
of the Council on Environmental Quality (40 CFR part 1500), and the
Department of Labor's NEPA procedures (29 CFR part 11) and has assessed
the environmental impacts. The Agency found that the final rule will
have no significant impact on air, water, or soil quality; plant or
animal life; the use of land; or other aspects of the human
environment.
2. Paperwork Reduction Act of 1995
The final rule contains no information collection or recordkeeping
requirements. Thus, there are no additional paperwork burden hours and
related costs associated with the final rule. Accordingly, the
Paperwork Reduction Act requires no further agency action or analysis.
3. The Unfunded Mandates Reform Act of 1995
MSHA has reviewed the final rule under the Unfunded Mandates Reform
[[Page 11299]]
Act of 1995 (2 U.S.C. 1501 et seq.). MSHA has determined that the final
rule does not include any Federal mandate that may result in increased
expenditures by State, local, or tribal governments; nor does it
increase private sector expenditures by more than $100 million in any
one year or significantly or uniquely affect small governments.
Accordingly, the Unfunded Mandates Reform Act of 1995 (2 U.S.C. 1501 et
seq.) requires no further agency action or analysis.
4. Treasury and General Government Appropriations Act of 1999
(Section 654: Assessment of Impact of Federal Regulations and Policies
on Families)
Section 654 of the Treasury and General Government Appropriations
Act of 1999 (5 U.S.C. 601 note) requires agencies to assess the impact
of Agency action on family well-being. MSHA has determined that the
final rule will have no affect on family stability or safety, marital
commitment, parental rights and authority, or income or poverty of
families and children. Accordingly, MSHA certifies that the final rule
will not impact family well-being.
5. Executive Order 12630: Government Actions and Interference with
Constitutionally Protected Property Rights
The final rule does not implement a policy with takings
implications. Accordingly, E.O. 12630 requires no further Agency action
or analysis.
6. Executive Order 12988: Civil Justice Reform
The final rule was written to provide a clear legal standard for
affected conduct and was carefully reviewed to eliminate drafting
errors and ambiguities, so as to minimize litigation and undue burden
on the Federal court system. Accordingly, the final rule meets the
applicable standards provided in section 3 of E.O. 12988, Civil Justice
Reform.
7. Executive Order 13045: Protection of Children from Environmental
Health Risks and Safety Risks
The final rule has no adverse impact on children. Accordingly,
under E.O. 13045, no further Agency action or analysis is required.
8. Executive Order 13132: Federalism
The final rule does not have ``federalism implications,'' because
it does not ``have substantial direct effects on the States, on the
relationship between the national government and the States, or on the
distribution of power and responsibilities among the various levels of
government.'' Accordingly, Executive Order 13132, Federalism, requires
no further agency action or analysis.
9. Executive Order 13175: Consultation and Coordination with Indian
Tribal Governments
The final rule does not have ``tribal implications,'' because it
does not ``have substantial direct effects on one or more Indian
tribes, on the relationship between the Federal government and Indian
tribes, or on the distribution of power and responsibilities between
the Federal government and Indian tribes.'' Accordingly, under E.O.
13175, no further Agency action or analysis is required.
10. Executive Order 13211: Actions Concerning Regulations That
Significantly Affect Energy Supply, Distribution, or Use
Executive Order 13211 requires agencies to publish a statement of
energy effects when a rule has a significant energy action that
adversely affects energy supply, distribution or use. MSHA has reviewed
the final rule for its energy effects because the final rule applies to
the coal mining sector. MSHA has concluded that the final rule is not a
significant energy action because it will not have significant adverse
effect on the supply, distribution, or use of energy. Further, because
the final rule will result in yearly costs of approximately $45,000 to
the coal mining industry, relative to annual revenues of $27.0 billion
in 2006, it is not a significant energy action because it is not likely
to have a significant adverse effect on the supply, distribution, or
use of energy. Accordingly, under this analysis, no further Agency
action or analysis is required.
11. Executive Order 13272: Proper Consideration of Small Entities in
Agency Rulemaking
MSHA has thoroughly reviewed the final rule to assess and take
appropriate account of its potential impact on small businesses, small
governmental jurisdictions, and small organizations. As discussed in
section VI.D of this preamble, MSHA has determined and certified that
the final rule would not have a significant economic impact on a
substantial number of small entities. Accordingly, Executive Order
13272, Proper Consideration of Small Entities in Agency Rulemaking,
requires no further agency action or analysis.
VII. Copy of the OSHA Reference Method (ORM)
MSHA's existing asbestos standards require that the analyst
determine fiber concentrations using a phase contrast microscopy
analytical method with 400-450X magnification. The ORM contains these
requirements. The definition of fiber in MSHA's final rule includes the
same characteristics as in the existing standards, i.e., longer than 5
[mu]m with a length to width ratio of at least 3:1. Although the ORM
requires counting fibers 5 [mu]m or longer, there is no practical
difference between these criteria considering the accuracy and
precision of the analytical methods. NIOSH Method 7400 is equivalent to
the ORM even though it requires counting fibers longer than 5 [mu]m.
The ORM also requires that analysts ``* * * must have taken the NIOSH
course for sampling and evaluating airborne asbestos dust or an
equivalent course.''
29 CFR 1910.1001 Appendix A: OSHA Reference Method--Mandatory
This mandatory appendix specifies the procedure for analyzing
air samples for asbestos and specifies quality control procedures
that must be implemented by laboratories performing the analysis.
The sampling and analytical methods described below represent the
elements of the available monitoring methods (such as Appendix B of
their regulation, the most current version of the OSHA method ID-
160, or the most current version of the NIOSH Method 7400). All
employers who are required to conduct air monitoring under paragraph
(d) of the [OSHA] standard are required to utilize analytical
laboratories that use this procedure, or an equivalent method, for
collecting and analyzing samples.
Sampling and Analytical Procedure.
1. The sampling medium for air samples shall be mixed cellulose
ester filter membranes. These shall be designated by the
manufacturer as suitable for asbestos counting. See below for
rejection of blanks.
2. The preferred collection device shall be the 25-mm diameter
cassette with an open-faced 50-mm electrically conductive extension
cowl. The 37-mm cassette may be used if necessary but only if
written justification for the need to use the 37-mm filter cassette
accompanies the sample results in the employee's exposure monitoring
record. Do not reuse or reload cassettes for asbestos sample
collection.
3. An air flow rate between 0.5 liter/min and 2.5 liters/min
shall be selected for the 25-mm cassette. If the 37-mm cassette is
used, an air flow rate between 1 liter/min and 2.5 liters/min shall
be selected.
4. Where possible, a sufficient air volume for each air sample
shall be collected to yield between 100 and 1,300 fibers per square
millimeter on the membrane filter. If a filter darkens in appearance
or if loose dust is seen on the filter, a second sample shall be
started.
5. Ship the samples in a rigid container with sufficient packing
material to prevent
[[Page 11300]]
dislodging the collected fibers. Packing material that has a high
electrostatic charge on its surface (e.g., expanded polystyrene)
cannot be used because such material can cause loss of fibers to the
sides of the cassette.
6. Calibrate each personal sampling pump before and after use
with a representative filter cassette installed between the pump and
the calibration devices.
7. Personal samples shall be taken in the ``breathing zone'' of
the employee (i.e., attached to or near the collar or lapel near the
worker's face).
8. Fiber counts shall be made by positive phase contrast using a
microscope with an 8 to 10 x eyepiece and a 40 to 45 x objective for
a total magnification of approximately 400 x and a numerical
aperture of 0.65 to 0.75. The microscope shall also be fitted with a
green or blue filter.
9. The microscope shall be fitted with a Walton-Beckett eyepiece
graticule calibrated for a field diameter of 100 micrometers (2 micrometers).
10. The phase-shift detection limit of the microscope shall be
about 3 degrees measured using the HSE phase shift test slide as
outlined below.
a. Place the test slide on the microscope stage and center it
under the phase objective.
b. Bring the blocks of grooved lines into focus.
Note: The slide consists of seven sets of grooved lines (ca. 20
grooves to each block) in descending order of visibility from sets 1
to 7, 7 being the least visible. The requirements for asbestos
counting are that the microscope optics must resolve the grooved
lines in set 3 completely, although they may appear somewhat faint,
and that the grooved lines in sets 6 and 7 must be invisible. Sets 4
and 5 must be at least partially visible but may vary slightly in
visibility between microscopes. A microscope that fails to meet
these requirements has either too low or too high a resolution to be
used for asbestos counting.
c. If the image deteriorates, clean and adjust the microscope
optics. If the problem persists, consult the microscope
manufacturer.
11. Each set of samples taken will include 10 percent blanks or
a minimum of 2 field blanks. These blanks must come from the same
lot as the filters used for sample collection. The field blank
results shall be averaged and subtracted from the analytical results
before reporting. A set consists of any sample or group of samples
for which an evaluation for this standard must be made. Any samples
represented by a field blank having a fiber count in excess of the
detection limit of the method being used shall be rejected.
12. The samples shall be mounted by the acetone/triacetin method
or a method with an equivalent index of refraction and similar
clarity.
13. Observe the following counting rules.
a. Count only fibers equal to or longer than 5 micrometers.
Measure the length of curved fibers along the curve.
b. In the absence of other information, count all particles as
asbestos that have a length-to-width ratio (aspect ratio) of 3:1 or
greater.
c. Fibers lying entirely within the boundary of the Walton-
Beckett graticule field shall receive a count of 1. Fibers crossing
the boundary once, having one end within the circle, shall receive
the count of one half (\1/2\). Do not count any fiber that crosses
the graticule boundary more than once. Reject and do not count any
other fibers even though they may be visible outside the graticule
area.
d. Count bundles of fibers as one fiber unless individual fibers
can be identified by observing both ends of an individual fiber.
e. Count enough graticule fields to yield 100 fibers. Count a
minimum of 20 fields; stop counting at 100 fields regardless of
fiber count.
14. Blind recounts shall be conducted at the rate of 10 percent.
Quality Control Procedures.
1. Intralaboratory program. Each laboratory and/or each company
with more than one microscopist counting slides shall establish a
statistically designed quality assurance program involving blind
recounts and comparisons between microscopists to monitor the
variability of counting by each microscopist and between
microscopists. In a company with more than one laboratory, the
program shall include all laboratories and shall also evaluate the
laboratory-to-laboratory variability.
2. Interlaboratory program.
a. Each laboratory analyzing asbestos samples for compliance
determination shall implement an interlaboratory quality assurance
program that as a minimum includes participation of at least two
other independent laboratories. Each laboratory shall participate in
round robin testing at least once every 6 months with at least all
the other laboratories in its interlaboratory quality assurance
group. Each laboratory shall submit slides typical of its own work
load for use in this program. The round robin shall be designed and
results analyzed using appropriate statistical methodology.
b. All laboratories should also participate in a national sample
testing scheme such as the Proficiency Analytical Testing Program
(PAT), or the Asbestos Registry sponsored by the American Industrial
Hygiene Association (AIHA).
3. All individuals performing asbestos analysis must have taken
the NIOSH course for sampling and evaluating airborne asbestos dust
or an equivalent course.
4. When the use of different microscopes contributes to
differences between counters and laboratories, the effect of the
different microscope shall be evaluated and the microscope shall be
replaced, as necessary.
5. Current results of these quality assurance programs shall be
posted in each laboratory to keep the microscopists informed.
[57 FR 24330, June 8, 1992; 59 FR 40964, Aug. 10, 1994]
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[[Page 11302]]
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List of Subjects
30 CFR Parts 56 and 57
Air quality, Asbestos, Chemicals, Hazardous substances, Metals,
Mine safety and health.
30 CFR Part 71
Air quality, Asbestos, Chemicals, Coal mining, Hazardous
substances, Mine safety and health.
Dated: February 22, 2008.
Richard E. Stickler,
Acting Assistant Secretary for Mine Safety and Health.
0
For the reasons set out in the preamble, and under the authority of the
Federal Mine Safety and Health Act of 1977, MSHA is amending chapter I
of title 30 of the Code of Federal Regulations as follows.
PART 56--SAFETY AND HEALTH STANDARDS--SURFACE METAL AND NONMETAL
MINES
0
1. The authority citation for part 56 continues to read as follows:
Authority: 30 U.S.C. 811.
0
2. Section 56.5001 is amended by revising paragraph (b) to read as
follows:
Sec. 56.5001 Exposure limits for airborne contaminants.
* * * * *
(b) Asbestos standard--(1) Definitions. Asbestos is a generic term
for a number of hydrated silicates that, when crushed or processed,
separate into flexible fibers made up of fibrils. As used in this
part--
Asbestos means chrysotile, cummingtonite-grunerite asbestos
(amosite), crocidolite, anthophylite asbestos, tremolite asbestos, and
actinolite asbestos.
Fiber means a particle longer than 5 micrometers ([mu]m) with a
length-to-diameter ratio of at least 3-to-1.
(2) Permissible Exposure Limits (PELs)--(i) Full-shift limit. A
miner's personal exposure to asbestos shall not exceed an 8-hour time-
weighted average full-shift airborne concentration of 0.1 fiber per
cubic centimeter of air (f/cc).
(ii) Excursion limit. No miner shall be exposed at any time to
airborne concentrations of asbestos in excess of 1 fiber per cubic
centimeter of air (f/cc) as averaged over a sampling period of 30
minutes.
(3) Measurement of airborne fiber concentration. Fiber
concentration shall be determined by phase contrast microscopy using a
method statistically equivalent to the OSHA Reference Method in OSHA's
asbestos standard found in 29 CFR 1910.1001, Appendix A.
* * * * *
PART 57--SAFETY AND HEALTH STANDARDS--UNDERGROUND METAL AND
NONMETAL MINES
0
3. The authority citation for part 57 continues to read as follows:
Authority: 30 U.S.C. 811.
0
4. Section 57.5001 is amended by revising paragraph (b) to read as
follows:
Sec. 57.5001 Exposure limits for airborne contaminants.
* * * * *
(b) Asbestos standard--(1) Definitions. Asbestos is a generic term
[[Page 11304]]
for a number of hydrated silicates that, when crushed or processed,
separate into flexible fibers made up of fibrils. As used in this
part--
Asbestos means chrysotile, cummingtonite-grunerite asbestos
(amosite), crocidolite, anthophylite asbestos, tremolite asbestos, and
actinolite asbestos.
Fiber means a particle longer than 5 micrometers ([mu]m) with a
length-to-diameter ratio of at least 3-to-1.
(2) Permissible Exposure Limits (PELs)--(i) Full-shift limit. A
miner's personal exposure to asbestos shall not exceed an 8-hour time-
weighted average full-shift airborne concentration of 0.1 fiber per
cubic centimeter of air (f/cc).
(ii) Excursion limit. No miner shall be exposed at any time to
airborne concentrations of asbestos in excess of 1 fiber per cubic
centimeter of air (f/cc) as averaged over a sampling period of 30
minutes.
(3) Measurement of airborne fiber concentration. Fiber
concentration shall be determined by phase contrast microscopy using a
method statistically equivalent to the OSHA Reference Method in OSHA's
asbestos standard found in 29 CFR 1910.1001, Appendix A.
* * * * *
PART 71--MANDATORY HEALTH STANDARDS--SURFACE COAL MINES AND SURFACE
WORK AREAS OF UNDERGROUND COAL MINES
0
5. The authority citation for part 71 continues to read as follows:
Authority: 30 U.S.C. 811, 951, 957.
0
6. Section 71.701 is amended by revising paragraphs (c) and (d) to read
as follows:
Sec. 71.701 Sampling; general requirements.
* * * * *
(c) Where concentrations of airborne contaminants in excess of the
applicable threshold limit values, permissible exposure limits, or
permissible excursions are known by the operator to exist in a surface
installation or at a surface worksite, the operator shall immediately
provide necessary control measures to assure compliance with Sec.
71.700 or Sec. 71.702, as applicable.
(d) Where the operator has reasonable grounds to believe that
concentrations of airborne contaminants in excess of the applicable
threshold limit values, permissible exposure limits, or permissible
excursions exist, or are likely to exist, the operator shall promptly
conduct appropriate air sampling tests to determine the concentration
of any airborne contaminant which may be present and immediately
provide the necessary control measures to assure compliance with Sec.
71.700 or Sec. 71.702, as applicable.
0
7. Section 71.702 is revised to read as follows:
Sec. 71.702 Asbestos standard.
(a) Definitions. Asbestos is a generic term for a number of
hydrated silicates that, when crushed or processed, separate into
flexible fibers made up of fibrils. As used in this part--
Asbestos means chrysotile, cummingtonite-grunerite asbestos
(amosite), crocidolite, anthophylite asbestos, tremolite asbestos, and
actinolite asbestos.
Fiber means a particle longer than 5 micrometers ([mu]m) with a
length-to-diameter ratio of at least 3-to-1.
(b) Permissible Exposure Limits (PELs)-- (1) Full-shift limit. A
miner's personal exposure to asbestos shall not exceed an 8-hour time-
weighted average full-shift airborne concentration of 0.1 fiber per
cubic centimeter of air (f/cc).
(2) Excursion limit. No miner shall be exposed at any time to
airborne concentrations of asbestos in excess of 1 fiber per cubic
centimeter of air (f/cc) as averaged over a sampling period of 30
minutes.
(c) Measurement of airborne fiber concentration. Fiber
concentration shall be determined by phase contrast microscopy using a
method statistically equivalent to the OSHA Reference Method in OSHA's
asbestos standard found in 29 CFR 1910.1001, Appendix A.
[FR Doc. E8-3828 Filed 2-28-08; 8:45 am]
BILLING CODE 4510-43-P